KR102600348B1 - Device for blocking a fluid pipe and Method for using the same - Google Patents

Abstract

This institute is a technology related to a fluid blocking means that temporarily blocks the fluid flow inside a fluid transfer pipe easily and safely even in a narrow work space of about 1 meter.
The non-stop device disclosed herein has a clockwise thread and a counterclockwise thread when a fluid block installed at the end of the rotating shaft is threaded at the end of the rotating shaft of the non-stop device that functions in conjunction with the wing receiving portion, the moving wing portion, and the moving jack. The movable jack is formed to have a directional thread structure and has a central bend on the outer edge of the thread, and is installed on both sides of the rotating shaft. The upper and lower transport rings of the movable jack are a movable structure in which the movable jack narrows or expands according to the rotation of the rotating shaft. Provided, the mobile jack has a structure in which semicircular moving wings forming an outer curved surface corresponding to the shape of the inner peripheral surface of the fluid transfer pipe are fixed, and the wing receiving part has a partial space formed on both sides of the cylindrical side wall and both sides of the partial space. The moving jack and the semicircular moving wing fixed to the moving jack provide a space for close contact/accommodation while also serving as an intermediate block, so that when the rotating shaft is rotated at an external position of the fluid transfer pipe, the moving wing part expands or narrows. It is characterized by an uninterrupted water supply device provided to open and close the fluid blocking port inside the fluid transfer pipe.

Description

An uninterrupted water supply device that functions to open and close the fluid blocking port inside the fluid transfer pipe from the outside and an uninterrupted water shutoff method using the same {Device for blocking a fluid pipe and Method for using the same}

The present invention is an uninterrupted water supply device applied so that a rotating shaft rotated from the outside can open and close the fluid blocking port inside the fluid transport pipe when it is desired to block the flow of a fluid such as tap water flowing inside a sealed fluid transfer pipe, and an uninterrupted water supply of the above configuration. It is a technology related to uninterrupted water blocking applied to control fluid flow using a device.

In general, many pipes to supply water used in buildings such as buildings or apartments or in various industrial sites are buried underground. However, due to factors such as the expansion of the outer perimeter of existing buildings or factories and the construction of new buildings, existing pipes are It is necessary to create a branch pipe or remove a certain portion of the existing pipe.

The pipes that supply water come in various sizes, from large pipes with a diameter of about 1.5m to 2m to small diameter pipes with a diameter of 150mm and 100mm. Devices that block these pipes and perform branch pipe work or pipe removal work are used in the past. In order to repair or replace such existing large pipes, water shutoffs in the area may raise many civil complaints from ordinary households, and in cases such as semiconductor factories, if the water supply is interrupted, the entire process is interrupted. In industrial sites where water supply must be shut off, even a brief water outage can cause significant economic loss.

As a means of solving the above problems, an uninterrupted water shutoff method has been developed and used to partially block the water flow only in the work area without turning off the water during the process of performing various necessary work on the existing pipe.

For example, in Republic of Korea Patent No. 10-0979443, a technology related to a pipe blocking device for an uninterrupted water shutoff method, a body is inserted into the inside of the pipe in a direction that intersects the direction of fluid flow, and a body is supported on the body and crosses the longitudinal direction of the pipe. A configuration comprising a middle blocking plate disposed in a direction, and a pair of left and right pipe side blocking plates coupled to both ends of the middle blocking plate and facing each other with respect to the back surface of the middle blocking plate and the upper and lower center line direction. Pipe blocking devices have been proposed and used.

However, if the large water pipe is damaged or deteriorated and needs to be replaced, even if the above-described uninterrupted water technology is used in the section requiring replacement, it branches into the main pipe and branch pipe, and a shut-off valve must be installed at the branching point to provide complex water supply. In the structure, for example, when the valve becomes old and needs to be replaced, replacement of the valve a installed on the branch pipe (2) is required, as shown in the application example diagram in FIG. 1 where the branch pipe and valve are connected and used in the fluid supply pipe in the prior art. When necessary, the work method is to replace valve a with valve b blocked. The water supply range is A, but in order to replace valve b, valve c must be blocked, so the water supply range is expanded to B.

Moreover, in order to block the c valve, which is a valve directly branched from the main pipe (1), the main pipe itself must be blocked, so there is a problem in that the range of water disconnection increases exponentially, such that all areas branched off from the main pipe must have water shut off. .

As a means of solving the above problems, in the prior art, two uninterrupted live sperm pipes are installed in a narrow range on both sides of the problematic section, and after drilling both sides of the water pipe using a perforator, rubber is inserted into the inside of the perforated water pipe. By inserting and inflating a balloon, etc., the water pipe is blocked only in a narrow section. Since a ball valve, etc. is installed in the uninterrupted water pipe, the ball valve is blocked when restoration is completed to prevent water from flowing out of the perforated area. It is used only once. There was a problem in that the live sperm tube and valve could not be reused because they were buried while connected to the tube.

In addition, the conventional technology can be applied to large-diameter water pipes or wide terrain conditions, but the continuous water method cannot be applied to narrow-diameter conditions such as 150mm or 100mm branch pipes, and the work space is limited to a width of less than 1 meter. There was a problem that there was no alternative to apply in the terrain conditions.

The present invention is intended to solve the above-mentioned problems, and is a fluid blocking means that is easy, safe, and more economical even in a narrow work space of about 1 meter. A fluid blocking port is installed at the end of a rotating shaft that can be rotated from the outside, and a fluid transfer pipe is provided. The purpose is to provide an uninterrupted water device that functions to push the fluid shutoff port inside and expand or fold the fluid shutoff port inside the fluid transfer pipe.

Additionally, the present application has the purpose of providing a continuous water supply method using a continuous water supply device.

In order to achieve the above objective, the technical idea disclosed herein is characterized by an uninterrupted water device that functions to allow a fluid block that can be rotated from the outside to be opened or closed inside the fluid transfer pipe, making work easier and safer and more economical. A secured fluid blocking means is disclosed.

The fluid blocking means to which the technical idea of this application is applied is a clockwise thread when the fluid blocking device installed at the end of the rotating shaft is threaded at the end of the rotating shaft of the sub-stop device that functions in connection with the wing receiving part, the moving wing part, and the moving jack. A movable jack is formed to have a counterclockwise thread structure and has a central bend on the outer edge of the thread, and is installed on both sides of the rotating shaft. The transfer table of the movable jack is provided as a moving structure in which the movable jack narrows or unfolds according to the rotation of the rotating shaft. ,

The moving jack has a structure in which semicircular moving wings forming an outer curved surface corresponding to the shape of the inner peripheral surface of the fluid transfer pipe are fixed,

The wing receiving part is provided with a structure in which a partial space is formed on both sides of the cylindrical side wall, and a space is provided in the partial space where the moving jack and the semicircular moving wing fixed to the moving jack are closely adhered to/accommodated, while also serving as an intermediate block.

It is characterized by an uninterrupted water device that includes a structure that allows the fluid blocking port inside the fluid transfer pipe to open and close while the moving wings unfold or form a folding structure when the rotating shaft is rotated at a position outside the fluid transfer pipe.

The non-stop device disclosed herein has a structure in which a jack is installed on a vertical pole surrounding the outer edge of the rotating shaft, and a fixed external cylinder with gears is installed on the outer edge of the vertical vertical rod, so that the vertical vertical rod and the rotating shaft are moved up and down by the operation of the gear of the fixed external cylinder. It can be applied so that the fluid blocker can enter the inside of the fluid transfer pipe by forming a structure, and at this time, the technical idea that can be applied by installing a saddle with a saddle rotation ball between the fixed external cylinder and the fluid transfer pipe is also included.

In the single-stage device to which the present technology is applied, the moving wing portion has a structure in which the outer support axis is connected between two wing plates forming an outward curved portion, and the center between the two wing plates is provided in a configuration with an empty space, and the outer edge of the moving wing portion is provided. When the bending part of the movable jack is combined with the support shaft and the movable jack unfolds with a wide gap between the top and bottom, it adheres to the rotating shaft in the empty space between the two wing plates, forming a structure with a reduced fluid block, and when the movable jack narrows, the two wings It is characterized by a configuration in which the semicircular outer edge portion is applied to form a structure that blocks the flow of the fluid transfer pipe as the plate expands to the outer edge.

Therefore, the present application is an uninterrupted water method in which a fluid block coupled to the end of the rotating shaft of the uninterrupted water device enters the inside of the fluid transfer pipe to control the fluid flow. A jack is installed on the vertical rod surrounding the outer edge of the rotating shaft of the uninterrupted water device. The outer edge of the enclosed rod has a structure in which a fixed outer cylinder with gears is installed, so that the vertical moving rod and the rotating shaft move up and down by the operation of the gears of the fixed outer cylinder, and a saddle rotating ball is installed between the fixed outer cylinder and the fluid transfer pipe. The fluid blocker installed at the end of the rotation shaft of the secondary disconnect device has a clockwise thread and a counterclockwise thread structure when a screw thread is formed at the end of the rotation shaft of the non-disruptive device connected to the wing receiving portion, the moving wing portion, and the moving jack. A movable jack is formed to have a central bend on the outer edge of the thread and is installed on both sides of the rotating shaft. The transfer table of the movable jack is provided as a movable structure in which the movable jack narrows or expands according to the rotation of the rotating shaft, and the movable jack has a fluid. It has a structure in which semicircular movable wings forming an outer curved surface corresponding to the shape of the inner peripheral surface of the pipeline are fixed, and the wing receiving portions have a partial space formed on both sides of the cylindrical side wall and are fixed to a moving jack and a moving jack on the side of the partial space. It is provided in a structure where the semicircular moving wings provide a space for close contact/accommodation and also serve as an intermediate block, so that the fluid flow inside the fluid transfer pipe is expanded or folded by rotating the rotating shaft at the external position of the fluid transfer pipe. It can be implemented in an endless method including a configuration that is applied to control fluid flow while forming a supporting structure. When the present technology is desired to be applied to a large-diameter fluid transfer pipe, it can be used in conjunction with a live sperm pipe, and a small-diameter fluid transfer pipe can be used in conjunction with the active sperm pipe. When the present technology is desired to be applied to a fluid transfer pipe, it can be used in conjunction with birds.

The technology using the continuous water shut-off device according to the present invention has the effect of providing a fluid blocking means that allows easy and safe work even in a narrow work space of about 1 meter and ensures greater economic efficiency.

The fluid blocking means provided by the present technology has a fluid blocking device installed at the end of a rotating shaft that can be rotated from the outside, and has the function of pushing the fluid blocking device into the fluid transfer pipe and expanding or collapsing the fluid blocking device inside the fluid transfer pipe. Through the simple configuration of the water shut-off device, the water cut-off area is narrowed to a minimum and the interruption time of fluid supply during construction is minimized, providing the effect of resolving civil complaints.

In addition, by using birds together with the original technology, it has the advantage of being much more economical and easier to work with than the conventional method of closing the fluid pipe using a live sperm pipe.

Figure 1: An application example in which a branch pipe and a valve are connected and used in a fluid supply pipe in the prior art.
Figure 2: Illustration of the application of the fluid block provided by the technical idea of this institute
Figure 3: Illustration of the coupling structure of the fluid block shown in Figure 2
Figure 4: An example of the exploded structure of the fluid block at the hospital.
Figure 5: Illustration of field application of the fluid block at our center.

Hereinafter, with reference to the attached drawings, a fluid pipe blocking method and a fluid pipe blocking device according to a preferred embodiment of the present invention will be described in more detail. However, the embodiment presented herein will be described in the case where the fluid transfer pipe is applied as a water supply pipe. Although the description is given as an example, it goes without saying that the fluid pipe in the present invention is not limited to just a water pipe.

Figure 2 shows an application example of the fluid block provided by the technical idea of the present application, Figure 3 shows a drawing for explaining the coupling structure of the fluid block presented in Figure 2 in various forms, and Figure 4 shows the fluid block provided by the present application. It shows the exploded perspective view of the sphere, and Figure 5 shows an example of field application of the fluid blocking sphere of our institution.

Referring to FIGS. 2 to 4 to explain the structure of the fluid block provided in the technical spirit of the present application, the fluid block 50 installed at the end of the rotating shaft 10 includes a wing receiving portion 40 and a moving wing portion 20. ) and the mobile jack 30 can be applied as an intermittent device in connection with the rotating shaft 10. More specifically, when the thread 11 is formed at the end of the rotating shaft 10, the clockwise thread 11a and A moving shaft ( 31) is installed and applied to form a structure in which the moving jack unfolds or folds around the central bend along the vertical movement ring (32) between the clockwise thread (11a) and the counterclockwise thread (11b) of the rotation axis, and the wing The receiving part 40 has a cylindrical shape and has a stepped expansion part 41a between the upper fixing part 41 and the bottom receiving part 42, and a partial space part 42a on both sides of the cylindrical side wall of the bottom receiving part 42. is formed and applied to the partial space portions 42a on both sides to provide a space in which the moving shaft 31 and the semicircular moving wing portion 20 fixed to the central bent portion 33 of the moving jack are closely adhered to/accommodated.

The moving wing portion 20 is provided with two moving wing portions having an outer curved surface structure to correspond to the shape of the inner peripheral surface of the fluid transfer pipe 1, which is provided in a circular shape. For example, the right moving wing portion has two side wall plates 21a, 21b) and a middle plate (21c) for connecting a portion of the center between the two side wall plates is combined with the two left and right side wall plates (21a, 21b) to form the moving wing portion of the right wing (21) using the same method. The left wing 22 is formed to form a structure corresponding to each other, so that when the two moving wings are unfolded, the outer curved surface of the moving wing part is provided in a structure that can be in close contact with the inner peripheral surface of the fluid transfer pipe 1, which is provided in a circular shape, In addition, concave spaces 21d are formed on both sides at the middle position of the middle plate 21c, which connects the two side wall plates 21a and 21b forming a semicircle, and are formed on both the upper and lower sides of the middle plate 21c. The concave space portion (21d) has a moving axis (31) spread up and down and forms a structure in which the right wing (21) and the left wing (22) are in close contact with each other, so that the moving axis (31) is inserted into the concave space portion (21d). It is applied to form a convenient structure without being limited by the close contact structure, and the middle plate (21c) is provided in a curved structure with a size and structure corresponding to the inner diameter of the fluid transfer pipe, so it is different from the two side wall plates (21a, 21b). The right wing 21 is formed by joining by a method such as welding, and the central bent portion 33 of the mobile jack 30 is formed between the coupling holes 21e formed in both side wall plates 21a and 21b of the right wing 21. The right wing 21 is coupled to the central bent portion 33 of the movable jack so that the coupling hole 33a formed in is positioned, and the left wing 22 is also coupled to the central bent portion 33 of the movable jack. When the moving jack along the lower moving ring (32) is folded around the central bent portion (33) and the right wing (21) and left wing (22) are narrowed in close contact, the right wing (21) and left wing (22) The ends of the facing side wall plates are combined to form a structure that does not collide with each other, and are applied to form a structure in which the moving wing portion 20 is accommodated in the partial space portion 42a formed on both sides of the bottom receiving portion 42, and the middle plate ( The moving shaft 31 is inserted into the concave space portion 21d formed on both the upper and lower sides of 21c) and is provided as a concave space portion 21d in the form of a concave groove of a size to accommodate the moving axis so as not to be restricted.

In Figure 2, the wing receiving portion 40 is It forms a structure that is fixed to the rotating shaft 10 through a coupling hole 40a, and is configured to be inside the partial space 42a formed on both sides of the cylindrical bottom receiving portion 42. Although it is not visible in the drawing, the right wing 21 and left wing 22 coupled to the central bending part 33 of the moving axis 31 are in an unfolded state and the partial space part of the bottom receiving part 42 ( The central portion (42b) without 42a) indicates that it can be provided as a structure that also serves as an intermediate blocking, and the solid line (22e) of the left wing portion (22) indicates that the intermediate plate (21c) is welded to the side wall plate on one side. This shows the part that was cut and welded to have a surplus space surrounding the side wall plate on the other side. The parts forming the right wing (21) and left wing (22) are made of metal that does not easily corrode, such as stainless steel. It is desirable that it be provided so that it can withstand high water pressure.

Figure 3 is a drawing to explain the application mode of the coupling structure of the fluid block shown in Figure 2, and is a drawing showing the bottom receiving part 42 of the wing receiving part 40 only with a solid line so that the rotation axis is visible to the outside ( In a), the screw thread 11 formed at the end of the rotating shaft 10 is formed to have a clockwise screw thread 11a and a counterclockwise screw thread 11b structure, and an up and down moving ring (up and down) moves up and down in conjunction with the screw thread. 32) This shows the state in which the right wing (21) and left wing (22) on both sides are not coupled to the central bent part (33) of the mobile jack with the gap between them narrowed as much as possible, and (b) shows the upper and lower wings (21) as in (a). , The right wing (21) and left wing (22), which had been separated while the space between the lower moving rings (32) was narrowed as much as possible, were combined with the central bent portion (33) and the space between the upper and lower moving rings (32) was narrowed as much as possible. This shows an embodiment in which the right wing 21 and the left wing 22 are spread on both sides to form a circular structure and are applied in close contact with the circular inner diameter of the fluid transfer pipe. In (c), they are interlocked with the thread of the rotation axis 10 to form a circular structure. It shows the shape of the right wing (21) and left wing (22) on both sides separated without being joined with the upper and lower moving rings (32) moving downwards widened as much as possible. In (d), (c) As shown in the figure, when the space between the upper and lower moving rings 32 is widened as much as possible and the separated right wing 21 and left wing 22 are closely adhered to form a structure in which the fluid is narrowed, the fluid blocking port 50 of the hospital becomes fluid. This shows that it can be applied in a structure as narrow as possible so that it can be interpolated into the fluid transfer pipe through the drilled hole formed in the pipe.

Figure 4 shows the structure of the moving wing portion in the form of an exploded perspective view of the wing receiving portion 40, the moving wing portion 20, the moving jack 30, and the rotating shaft 10 before the fluid blocking device 50 of the present application is combined. In order to explain this, the right wing 21 and the left wing 22 have a middle plate 21c with concave spaces 21d formed on both sides at an intermediate position between the two side wall plates 21a and 21b forming a semicircular shape. ), the two side wall plates (21a, 21b) are joined by a method such as welding to form the movable wing portion (20), and the movable jack is inserted between the coupling holes (21e) formed in both side wall plates (21a, 21b) of the movable wing portion. The coupling hole 33a formed in the central bent portion 33 is located so that the movable wing portion 20 is coupled to the central bent portion 33 of the movable jack, and the movable jack 30 and the movable wing portion 20 ) is accommodated in the partial space portion (42a) formed on both sides of the circular side wall of the bottom receiving portion (42) of the wing receiving portion, and the space between the upper and lower moving rings (32) of the moving jack (30) is widened as much as possible, and the right wing (21) And the left wing (22) is in close contact with each other as much as possible to form a narrow structure and is interpolated into the drilled hole (3) of the fluid transfer pipe (1), and then the space between the upper and lower moving rings (32) of the moving jack (30) is narrowed as much as possible to form the right wing. (21) and the left wing (22) form a structure that presses the inner wall of the fluid transfer pipe (1), and the gap between the right wing (21) and the left wing (22) is the central part (42b) of the wing receiving portion (40). This shows that it plays the role of an intermediate block and can be applied to form a fluid blocking structure.

In addition, the rotation axis 10 of the present invention forms a structure integrally coupled with the moving body 70 and is applied to move up and down. A rack gear built-in groove 72 is formed on one side of the moving body 70 and the built-in groove It has a structure with a built-in rack gear 71, and the outer diameter of the upper fuselage 70 is provided to have the same outer diameter as the bottom accommodating part 42 of the wing receiving part 40, so that the lower part 70a of the upper fuselage 70 is provided. It has a structure that is fixed against the step expansion part (41a) of the false wing receiving part (40), and the rack gear (71) is moved as shown in FIG. 5 with the rotation axis (10) built in the center of the upper fuselage (70). It can be applied to move the vertical body 70 and the rotating shaft 10 installed inside the fixed outer cylinder up and down together in the fixed outer cylinder 80 having a gear 81 that can be It can be implemented as in the application example.

Figure 5 shows an aspect in which the fluid block 50 provided by the present technology can be applied in the field as an embodiment, (a) is shown in the form of a perspective view, and (b) is the fluid block 50 of the present invention. (c) shows the state of entering the inside of the fluid transfer pipe (1), and (c) shows that the fluid blocking port (50) of the hospital has right wings (21) and left wings (22) on both sides inside the fluid transfer pipe (1). It shows a structure that unfolds and presses on the inner wall of the fluid transfer pipe (1) to form a fluid blocking state, and the upper and lower sides of the fluid transfer pipe (1) subject to fluid blocking are wrapped and fixed with the flange pipe (2) and the connector (3). A saddle 90 with a built-in ball valve 91 is mounted on the upper part of the connector 3, and a vertical body 70 with a rack gear 71 installed on one side as shown in FIG. 4 is installed as a fixed external cylinder ( 80) By rotating the gear (gear: 81) installed on one side of the fixed external cylinder (80) while fixed inside, the vertical body (70) with the rack gear (71) built in and the rotating shaft (10) move up and down together. It shows an embodiment that can be applied to move.

Therefore, the method of blocking the fluid flowing inside the fluid transfer pipe to which the present technology is applied can be divided into a saddle installation step, a perforation step, a fluid blocking step, and a closure step, as an application example. Since the step is also applied in the conventional non-stop water technology, no separate explanation is needed, and the part where the technical idea of the present application is newly applied is that, as in the embodiment of (b) of Figure 5, the fluid blocking port 50 of the present application is a fluid transfer pipe ( 1), the right wing (21) and the left wing of the moving wing part installed at the lower part of the rotating shaft are formed by a simple operation of simply rotating the turning hole (60) of the rotating shaft installed at the upper end of the fixed external cylinder (80). The part applied to block the fluid transfer pipe by spreading the wing 22 inside the fluid transfer pipe as shown in (c) of FIG. 5 may be a feature of the present application.

In this application, the elastic packing is not shown in order to avoid complicating the configuration of the fluid blocking port 50, but the outer edges of the right wing 21 and the left wing 22 are aligned with the elastic packing toward the side wall of the fluid transfer pipe. It will be obvious to those skilled in the art that adhesion efficiency can be increased by being inserted into the outer edge of the left wing 22.

In the above, the technical idea of the present application has been described with reference to the drawings of an embodiment in which the technical idea is implemented, but this is merely illustrative, and various modifications and other equivalent embodiments can be made by those skilled in the art. It will be understood, and therefore, the true scope of patent protection of the present invention should be determined to be protected to the extent of equivalents in accordance with the claims presented herein.

1: Fluid transfer pipe 2: Upper and lower flange
3: Connector 4: Fastener
5: drilled hole 10: rotation axis
11: thread 20: moving wing part
21: right wing 22: left wing
30: moving jack 31: moving axis
32: Shanghai Dongling 33: Central bending part
40: wing receiving part 41: upper fixing part
41a: step expansion part 42: bottom receiving part
42a: partial space 50: fluid blocking port
60: Rotation axis turning rod 70: Shanghai fuselage
71: Rack gear 72: Rack gear built-in groove
80: fixed external cylinder 81: gear
100: Uninterrupted number device

Claims (5)

In the non-stop water device in which the fluid block 50 connected to the end of the rotating shaft 10 rotated from the outside enters the inside of the fluid transfer pipe 1 and functions to unfold or fold the fluid block inside the fluid transfer pipe,
The rotating shaft 10 has a rotating shaft structure at the top, a clockwise thread 11a and a counterclockwise thread 11b formed at the bottom, and the upper portion of the mobile jack 30 is formed on the outer edge of each thread. , The lower moving ring (32) is installed and is provided in a structure that can narrow or widen the gap between the upper and lower moving rings (32) according to the rotation of the rotating shaft,
The fluid blocking port 50 has a configuration in which the moving wing portion 20, the moving jack 30, and the wing receiving portion 40 are linked and interact with each other.
The moving wing unit 20 is provided with a right wing 21 and a left wing 22 in an outer curved structure to correspond to the shape of the inner peripheral surface of the fluid transfer pipe 1, which is provided in a circular shape, and the right wing 21 has two It has a structure in which a middle plate (21c) connects a portion of the center between the two side wall plates (21a, 21b) and a concave space (21d) is formed in the middle of both ends of the middle plate, and the two side wall plates (21a, 21b) are formed. 21b) is combined to form the right wing 21, and the left wing 22 is also formed in the same shape, so that the right wing and left wing 22 are unfolded inside the fluid transfer pipe 1. The outer curved surface is provided in a structure that can be in close contact with the inner peripheral surface of the fluid transfer pipe (1),
The movable jack 30 has a structure in which a movable shaft 31 is connected on both sides between the upper and lower movable rings 32 and has a central bent portion 33 at the middle position of the movable shaft. The coupling holes (33a, 33b) are combined with the coupling holes (21e, 22e) of the side wall plates of the right wing (21) and the left wing (22), and the gap between the up and down moving rings (32) is widened to increase the distance between the right wing (21) and the left wing (21). ) and the left wing 22 are combined to form a structure in which the opposing side wall plate ends of the right wing 21 and the left wing 22 do not collide with each other when the left wing 22 is narrowed. When the gap between the upper and lower moving rings 32 is narrowed according to the rotation of the screw threads 11a and 11b, the right wing 21 and the left wing 22 are formed to unfold, and the upper and lower moving rings 32 are formed. When the gap is widened, the right wing 21 and the left wing 22 enter and are accommodated between the partial spaces 42a of the wing receiving part 40.
The wing receiving portion 40 has a structure having a stepped expansion portion 41a between the cylindrical upper fixing portion 41 and the bottom receiving portion 42 at the upper position of the screw thread 11 of the rotating shaft 10 and receives the bottom portion. A partial space 42a is formed on both sides of the side wall of the portion 42, so that the right wing 21 and the left wing 22 can enter and be accommodated in the partial space 42a,
When an uninterrupted water operation is required, the fluid transfer pipe (1) is drilled, the fluid shutoff hole (50) is entered into it, and the upper and lower moving rings ( 32) The right wing 21 and the left wing 22 fixed to the central bent portion 33 between the valves are expanded or narrowed, characterized in that it includes a configuration applied to open or close the fluid blocking port. Uninterrupted device. delete According to paragraph 1,
The intermediate plate connecting the two side wall plates to form the moving wing portion 20 in the above-mentioned continuous water supply device is provided in a structure in which a curved portion is formed in a size corresponding to the inner diameter of the fluid transfer pipe. delete In the non-stop method in which the fluid block 50 connected to the end of the rotating shaft 10 rotated from the outside enters the inside of the fluid transfer pipe 1 and functions to unfold or fold the fluid block inside the fluid transfer pipe,
The rotation shaft 10 has a rotation axis rotation structure at the top , a clockwise thread 11a and a counterclockwise thread 11b at the bottom, and an upper portion of the mobile jack 30 at the outer edge of each thread. , The lower moving ring (32) is installed and is provided in a structure that can narrow or widen the gap between the upper and lower moving rings (32) according to the rotation of the rotating shaft,
The fluid blocking port 50 has a configuration in which the moving wing portion 20, the moving jack 30, and the wing receiving portion 40 are linked and interact with each other.
The moving wing unit 20 is provided with a right wing 21 and a left wing 22 in an outer curved structure to correspond to the shape of the inner peripheral surface of the fluid transfer pipe 1, which is provided in a circular shape, and the right wing 21 has two It has a structure in which a middle plate (21c) connects a portion of the center between the two side wall plates (21a, 21b) and a concave space (21d) is formed in the middle of both ends of the middle plate, and the two side wall plates (21a, 21b) are formed. 21b) is combined to form the right wing 21, and the left wing 22 is also formed in the same shape, so that the right wing and left wing 22 are unfolded inside the fluid transfer pipe 1. The outer curved surface is provided in a structure that can be in close contact with the inner peripheral surface of the fluid transfer pipe (1),
The movable jack 30 has a structure in which a movable shaft 31 is connected on both sides between the upper and lower movable rings 32 and has a central bent portion 33 at the middle position of the movable shaft. The coupling holes (33a, 33b) are combined with the coupling holes (21e, 22e) of the side wall plates of the right wing (21) and the left wing (22), and the gap between the up and down moving rings (32) is widened to increase the distance between the right wing (21) and the left wing (21). ) and the left wing 22 are combined to form a structure in which the opposing side wall plate ends of the right wing 21 and the left wing 22 do not collide with each other when the left wing 22 is narrowed. When the gap between the upper and lower moving rings 32 is narrowed according to the rotation of the screw threads 11a and 11b, the right wing 21 and the left wing 22 are formed to unfold, and the upper and lower moving rings 32 are formed. When the gap is widened, the right wing 21 and the left wing 22 enter and are accommodated between the partial spaces 42a of the wing receiving part 40.
The wing receiving portion 40 has a structure having a stepped expansion portion 41a between the cylindrical upper fixing portion 41 and the bottom receiving portion 42 at the upper position of the screw thread 11 of the rotating shaft 10 and receives the bottom portion. A partial space 42a is formed on both sides of the side wall of the portion 42, so that the right wing 21 and the left wing 22 can enter and be accommodated in the partial space 42a,
When uninterrupted water work is required, the fluid transfer pipe (1) is drilled, the fluid shutoff hole (50) is entered into the center bend between the upper and lower moving rings (32) by rotating the rotating shaft (10) at an external position. An uninterrupted water method, characterized in that the right wing (21) and the left wing (22) fixed to (33) are applied to enable fluid blocking work while forming a structure in which the right wing (21) and the left wing (22) are expanded or narrowed.