KR101041047B1 - Sealing apparatus for a Fluid Line Hole - Google Patents

Abstract

The present invention relates to a sealing stopper used to seal a fluid movement path such as a cooling pipe, and in particular, is made of a configuration to secure airtightness by expanding the expansion rubber ring provided in the state inserted into the fluid hole,

As the valleys are formed on the outer circumference of the expansion rubber ring and the peaks formed naturally above and below the valleys are in close contact with the fluid hole wall surface, the multi-sealing effect can be obtained with only one expansion rubber ring, and the structure is simple, thus producing cost. It also relates to a fluid hole closure cap which can be reduced as well as shorten the assembly time.

In addition, the bone fastening ring is provided with a separate bone fastening ring in the bone so that the bone fastening ring is in close contact with the fluid hole wall in the expansion process of the expansion rubber ring. The present invention relates to a fluid hole closure stopper that can prevent the entire plug from turning off.

Fluid, Sealed, Spigot, Rubber Ring

Description

Sealing apparatus for a Fluid Line Hole

The present invention relates to a fluid hole sealing stopper for sealing a fluid transfer path through which a fluid flows, such as a cooling pipe of a cooling device, to prevent leakage of fluid. By forming the part and providing a separate bone fastening ring in the bone part, not only can a multi-sealing effect be obtained with one expansion rubber ring, but also the structure of the product can be simplified, and the fluid hole sealing can obtain higher pressure resistance. It's about a stopper.

In general, a pipe or the like in which fluid is moved inside by a certain pressure is used to block the end of the fluid hole by using a separate sealing member to prevent unnecessary leakage at the end.

Conventionally, tapping is performed on the inner circumferential surface of the end of the fluid hole, and a sealing member having a tab bolt shape in which a sealing tape is wound is screwed to the end to seal.

However, this method is difficult to secure a certain air tightness because the airtightness is different depending on the winding state or the amount of the sealing tape, there is a problem that the work is cumbersome and inconvenient because the tap work of the pipe must always be accompanied for sealing.

Recently, in order to solve the problem of the tab bolt method, a rubber ring is provided on the outer circumferential surface, and a sealing member using a close contact between the rubber ring and the fluid hole has been proposed.

Among them, the Republic of Korea Utility Model No. 0393425 "cooling pipe stopper", the prior art, as shown in Figure 1, the first expansion rubber ring 20 is seated on the base portion 10 and the rubber thereon The ring mounting member 70 is positioned and the seat 34 is sequentially stacked with the second expansion rubber ring 20 ', the pressure plate 32, the expansion pressure ring 33, and the seat 34 sequentially stacked thereon. The center of the bolt 50 is penetrated so that the end is coupled to the center of the base portion 10.

In this state, when the bolt 50 is rotated in the state where the whole is inserted into the fluid hole P, the edges of the expansion rubber rings 20 and 20 'are expanded to the outside by the pressure between the respective components, Close contact with high pressure ensures airtightness.

At this time, since each expansion rubber ring 20, 20 'is positioned in the upper and lower double with the rubber ring installation member 70 therebetween, there is an advantage that high airtightness can be obtained when using one expansion rubber ring.

In addition, each expansion rubber ring (20, 20 ') is formed with a rim groove (20a) to increase the adhesion when pressed.

However, the prior art should be provided with a plurality of expansion rubber rings (20) and 20 'for the multi-seasonal and rubber ring installation member (70) must also be provided separately for each expansion rubber ring (20, 20') installation As a result, the total number of parts increases, which inevitably raises production costs.

In addition, as the number of parts increases, the assembly of each part becomes more cumbersome and the overall length increases, which may adversely affect the installation.

In the drawing, the expansion rubber ring is shown as two, but if there are more expansion rubber ring, each of the above problems are bound to be larger.

In addition, the expansion rubber ring (20, 20 ') has the effect that the edge groove (20a) is formed to increase the adhesion when pressurizing, the area that is in close contact with the inner surface of the pipe during pressurization is larger than when using the expansion rubber ring of the circular section There was almost no effect of improving adhesion due to no difference.

In the process of pressurizing the first bolt 50 by rotation, the stopper ring must be sufficiently secured between the expansion rubber rings 20 and 20 'and the inner surface of the pipe until the expansion pressure ring 33 is in close contact with the inner surface of the pipe. Pressurization continues smoothly,

As such, since the rotation of the stopper is prevented only by the frictional force of the expansion rubber ring until a certain point in the pressing process, there is a problem in that the entire stopper can not be sustained if the torque is greater than the frictional force in the process of continuously turning the bolt.

The present invention is proposed to solve the problems of the prior art as described above,

First, it is possible to obtain a multi-tight structure with only one expansion rubber ring, thereby simplifying the structure and reducing the number of parts compared to the existing multi-tight structure, and ultimately, to provide a fluid hole sealing plug that can lower production costs.

In addition, by providing an expansion rubber ring and a structure that can reinforce the frictional force with the fluid hole wall surface, the purpose is to provide a fluid hole closure plug that does not run even at a large torque than conventional pipes.

In addition, the present invention is intended to provide a fluid hole closure plug having a high pressure resistance as well as additional airtightness with the frictional force as a simple structure compared to the conventional.

The present invention proposed to achieve the above objects,

A base portion having a threaded portion formed in the upper center and a seating surface formed around the threaded portion, an expansion rubber ring seated on the seating surface of the base portion, a pressing portion positioned on the expansion rubber ring, and a position on the pressing portion Is made of a pressing member that is screwed with the base portion as a basic configuration,

The expanded rubber ring is formed by stacking a plurality of rubber rings of a circular cross section, and a valley portion having a predetermined depth is formed on the outer circumference, and an acid portion is naturally formed above and below the valley portion, and each acid portion is independently formed on the fluid hole wall surface. It is characterized by being in close contact.

And a separate bone fastening ring is inserted in the valley of the expansion rubber ring, characterized in that the outer surface of the bone fastening ring is in close contact with the fluid hole wall surface during the expansion of the expansion rubber ring.

In addition, the pressure plate is divided into a second pressure plate seated on the elastic ring and the first pressure plate laminated on the second pressure plate, divided into, each of the pressure plate between the fixing ring which is extended in close contact with the fluid hole wall surface It is characterized in that the further provided.

In addition, the surface of the fixing ring and the bone fastening ring is uneven, characterized in that to increase the friction with the fluid hole wall surface.

The present invention consisting of the above characteristic configuration,

First, since each peak located between the valleys in the expansion process of the expansion rubber ring is closely adhered to the fluid hole wall as in the conventional circular section rubber ring, the airtight is made multiple on one rubber ring.

Compared with the prior art, in which multiple expansion rubber rings have to be provided for multi-tightness, the number of parts can be reduced, thereby simplifying the structure, thereby making assembly easier, and reducing the production cost of the product.

In addition, when forming a plurality of valleys on one expansion rubber ring, the number of peaks is naturally increased by that, there is an advantage that can increase the airtight effect without increasing the number of parts.

In addition, the bone fastening ring inserted into the bone during the expansion of the expansion rubber ring is also extended to closely adhere to the fluid hole wall surface. Rotating the bolt with torque has the effect of preventing the plug from turning off.

In addition, because the joint fastening ring is also closely adhered to the fluid hole wall between the peaks of the extended rubber ring, not only an additional airtight effect can be obtained by the bone fastener ring, but also the joint fastening ring serves to reduce the pressure between the peaks. It is also possible to obtain an improved effect.

In addition, since the frictional force and the pressure resistance are improved by the bone fastening ring, there is no need to have a fixing ring that was used to prevent the back and forth movement of the stopper, and the number of the pressure plates is also reduced.

Hereinafter, with reference to the configuration illustrated in the drawings will be described embodiments of the specific configuration and its operation of the present invention.

The fluid hole closure plug of the present invention is composed of a base portion 10, an expansion rubber ring 20, a pressing portion 30 and a pressing member 50 as shown in [Fig. 2] to [4].

First, the base portion 10 is for installation and pressurization of the expansion rubber ring 20 to be described later is made of a structure provided with a seating plate 14 of the flange form at the bottom of the fastening pipe 12 formed with a screw portion on the inner circumferential surface.

At this time, the upper surface of the seating plate 14, that is, the flange surface (hereinafter referred to as 'sitting surface 15') is processed to form the irregularities to increase the friction force with the expansion rubber ring (20).

The expansion rubber ring 20 is for airtightness and internal pressure, which is a key role in the closure cap, basically has a circular ring shape in which the insertion hole 22 is formed in the center and the base portion 10 of the insertion hole 22. The coupling tube 12 is penetrated to the seating surface 15 of the base 10.

The expansion rubber ring 20 is made of a fluorine-based rubber material to have both elasticity and pressure resistance and fire resistance at the same time, the material is not necessarily limited to this, if the material having the above properties and ensures airtightness can be selectively applied. Do.

Expanded rubber ring 20 of the present invention, unlike the prior art in which the outline is made of a simple circular cross section, the bone 24 is formed at a predetermined depth on the outer circumference and relatively protruding from the upper and lower sides relative to the bone 24 The first and second peaks 26 and 27 are formed to have a double stacked conventional rubber ring having a circular cross section.

The reason for forming each of the peaks 26 and 27 through the valleys 20 is that the first and second peaks 26 and 27 separately serve the airtight and pressure-resistant roles of a conventional circular cross-section rubber ring. This is to achieve a multi-confidential effect.

In other words, each mountain part performs an independent expansion rubber ring function, thereby achieving the same effect as installing two circular cross-section expansion rubber rings at different locations, and reducing the number of assembly parts. It will be reduced.

At this time, the depth (A) of the bone 24 and the interval (pitch) (B) between the first and second peaks 26, 27, the bone 24 is the fluid hole (P) when the expansion rubber ring 20 is expanded The design should be such that the recessed shape can be maintained without being in close contact with the wall. In other words, even if it is expanded, each of the mountain (26, 27) is to ensure that the airtight respectively.

The reason for this is that when the stopper of the present invention is fastened to the fluid hole, a strong frictional force is generated with the inner wall of the fluid hole, or a torn portion of each of the peaks 26 and 27 is subjected to a long period of fluid pressure after the fastening. In the event of breakage, it is to prevent the breakage from the gap from progressing from the peak to the other peak, and to maintain the minimum sealing function with only the undamaged peak.

The inner diameter of the expansion rubber ring 20 is such that the fastening tube 12 of the base portion 10 is forcibly fitted and the outer diameter is slightly larger than the diameter of the fluid hole P so that friction force with the fluid hole is generated. When the pressure member 50 is first rotated in the inserted state, the pressure member 50 does not rotate together with the pressure member 50.

The pressing portion 30 for pressing the expansion rubber ring 20 and the fixing ring 40 to be described later is installed on the upper surface of the expansion rubber ring 20,

The pressing unit 30 includes a second pressing plate 32 for directly pressing the expansion rubber ring 20 and a first pressing plate 34 for pressing the fixing ring 40 to be described later.

The second pressing plate 32 is a circular body having the same outer diameter as the seating plate 14 of the base 10, the upper surface of the second recessed portion (32a) is formed while forming an inclined surface and the second recessed portion (34a) The bottom of the) is made of a structure in which a through hole 32b is formed that is the same as the inner diameter of the expansion rubber ring 20.

 And before describing the first pressure plate 34, a separate fixing ring 40 is first seated on the second pressure plate (32).

The fixing ring 40 prevents the forward and backward movement of the whole stopper in the state of being installed with the auxiliary airtight role separately from the expansion rubber ring 20, and when the stopper is in vain due to the frictional force with the wall of the fluid hole (P) To prevent the phenomenon, it is seated on the upper edge of the second pressing plate 32 in the form of a simple circular ring.

Since the fixing ring 40 has a role of fixing the position of the stopper rather than airtightness substantially, a metal material is used so that the fixing ring 40 can be closely adhered to the fluid hole P without strong shape deformation.

Of course, any material that can obtain sufficient hardness and strength in addition to the metal can be applied.

At this time, the fixed ring 40 is cut to a specific point 42 so that it can be easily extended to the outside when pressed by the first pressure plate 32, the outer diameter is made smaller than the diameter of the fluid hole (P) to stop the first Make sure the insertion is smooth.

In addition, the surface of the fixing ring 40 to form a fine concavo-convex by a separate sanding process, such as to increase the friction with the fluid hole (P) wall surface.

The first pressing plate 34 is a portion to which the pressing force generated from the pressing member 50 to be described later together with the pressing of the fixing ring 40 is first transmitted,

An inclined surface 34b corresponding to the second recessed portion 32a of the second pressing plate 32 is formed on the side surface to form a funnel shape.

In addition, a first recess 34a having a shape similar to that of the second recess 32a is formed on the upper surface so that the head 52 of the pressing member 50 to be described later is formed, and the first recess 34a of the first recess 34a is The bottom surface has a through hole 34c through which the bolt portion 56 of the pressing member 50 passes.

The first pressing plate 34 is stacked so that the lower inclined surface 34b spans the fixing ring 40, and the first pressing plate 34 is stacked in a state where a gap is formed between the first and second pressing plates 34 and 32.

The pressing member 50 is a portion which becomes the starting point of the entire pressing force simultaneously with the pressing of the first pressing plate 34,

Wrench groove 54 is formed in the head portion 52 in the form of a general countersunk bolt, and the bolt portion 56 has a through hole 32b of the first pressing plate 34 and a through hole 32b of the second pressing plate 32. ) Is sequentially passed through the end is inserted into the fastening tube 12 of the base portion 10 is screwed.

In this case, a sufficient gap is formed between the lower end of the bolt part 56 and the inner bottom surface of the fastening pipe 12, so that the bolt part 56 is caught on the bottom of the fastening pipe 12 and can no longer rotate during the rotation process. To prevent.

Next will be described the operation of the embodiment and the unique effects generated in the process.

 First, as shown in FIG. 3, the entire components are inserted into the fluid hole P as shown in FIG.

As described above, the outer diameter of the expansion rubber ring 20 is made slightly larger than the diameter of the fluid hole P. In the inserted state, the outer surface of each of the peaks 26 and 27 has a constant pressure on the wall of the fluid hole P. It will be in close contact.

In this state, when the wrench (not shown) is inserted into the head 52 of the pressure member 50 and the bolt 56 is screwed into the fastening tube 12 of the base 10, the pressure member 50 is rotated. The whole is moved downward.

At this time, the base portion 10 is also going to rotate together, but the base portion 10 is in close contact with the expansion rubber ring 20 by the unevenness of the seating surface 15, and the expansion rubber ring 20 is the fluid hole as described above. Since it is in close contact with (P), it cannot be rotated.

As the pressing member is screwed in the state in which the base portion 10 is fixed, the pressing member 50 may be smoothly moved into the fastening tube 12 while rotating.

As the pressing member 50 moves downward, the head 52 pushes the first pressing plate 34, and the first pressing plate 34 presses the fixing ring 40.

In this process, the inclined surface 34b of the first pressing plate 34 is applied to the fixing ring 40 by the force to be extended toward the outside and the force pressed downward.

Therefore, the fixing ring 40 presses the second pressure plate 32 and the second pressure plate 32 presses the upper surface of the expansion rubber ring 20.

As the expansion rubber ring 20 is pressurized from above, the outer circumference of the expansion rubber ring 20 is expanded as shown in FIG. The power to try (see arrow) is applied.

As shown in FIG. 5, when the height of the expansion rubber ring 20 is contracted by (a) by pressing force, each of the peaks 26 and 27 and the valleys 27 are expanded toward the outside by (a '). As the adhesion between the peaks 26 and 27 and the wall of the fluid hole P increases, the airtightness also increases.

In this case, since the shape of the valley part 24 is maintained even as described above, the first and second mountain parts 26 and 27 are separated from each other with the valley part 24 interposed therebetween, so as to be in close contact with the fluid hole P wall. Each mountain portion 26, 27 is a double hermetic.

That is, a double hermetic structure is implemented by only one expansion rubber ring 20.

Although the curved groove 20a is formed in the expansion rubber ring of the prior art as shown in FIG. 1, the prior art has a structure in which the entire groove 20a is in close contact with the fluid hole (P) wall when expanding. As in the invention, the double hermetic structure by the mountains 26 and 27 cannot be implemented.

As described above, the present invention according to the embodiment forms a valley 24 and a hill 26 and 27 on one expansion rubber ring 20, unlike the prior art in which multiple expansion rubber rings should be provided for multiple airtightness. As the multiple airtightness is achieved by each of the peaks 26 and 27, the number and structure of the parts are simplified, so that the assembly is easy and the cost of the product can be lowered.

When the pressure member 50 is continuously rotated in the airtight state by the expansion of the expansion rubber ring 20 as shown in FIG. 6A, the fixing ring 40 is pushed to the first pressure plate 34 to expand the fluid around the outer shell. It adheres on the wall of the hole P.

In this state, even if the torque of the pressure member 50 becomes greater than the friction force of the expansion rubber ring 20, the friction force between the fixing ring 40 and the wall of the fluid hole is also being acted on. do.

6B, if more than one valley 24 is formed in the expansion rubber ring 20, the number of peaks 26 and 27 also increases, so that a more multi-confidential structure can be obtained.

Various features of the present invention described above may be modified in various forms. [7] to [9] illustrate a second embodiment of the present invention.

 As shown in the drawing, the second embodiment has the same basic structure as the previous embodiment, but is further provided with a separate bone fastening ring 60 at the valley part 24 of the expansion rubber ring 20.

 More specifically, the bone fastening ring 60 has a stopper by further enhancing the airtightness of the expansion rubber ring 20 and the pressure resistance to the fluid and reinforcing the friction force between the expansion rubber ring 20 and the fluid hole P. Hollow is to prevent the phenomenon, the cross-sectional area is made relatively small in the form of a simple steel ring, such as a fixed ring (40).

The bone fastening ring 60 is inserted to surround the entire valley portion 24 of the expansion rubber ring 20 and cut a specific point so that it can be expanded smoothly together when the expansion rubber ring 20 is pressed.

When the expansion rubber ring 20 is pressed in the same manner as in the previous process in the state in which the bone fastening ring 60 is installed, each mountain portion 26 having a relatively large diameter is expanded as shown in FIG. 6. 27) is strongly adhered to the wall of the fluid hole P first.

In this state, if pressure is additionally applied, as the bone part 24 is also expanded and the bone fastening ring 60 is pushed outward, the bone fastening ring 60 is also expanded together so that the outer circumference of the bone fastening ring 60 is fluid hole. (P) It adheres to the wall.

Therefore, in this state, even if the torque of the pressure member 50 is greater than the maximum frictional force of the expansion rubber ring 20, because the frictional force between the bone fastening ring 60 and the fluid hole (P) additionally acts as a whole stopper The phenomenon is prevented.

In addition, since the bone fastening ring 60 is a metal material, the contact surface is not deformed during the close contact with the fluid hole, so that the close contact force is not canceled, and thus the close contact ring 60 may be closely contacted with a high pressure.

That is, even if the torque exceeds the frictional force of the expansion rubber ring 20 before the fixing ring 40 is in close contact with the fluid hole wall, the frictional force is prevented because the frictional force is reinforced by the bone fastening ring 60. .

In addition, as in the fixing ring 40, the surface of the bone fastening ring 60 may also obtain greater frictional force by forming fine unevenness through sanding.

In addition, as the bone fastening ring 60 is closely adhered to the wall between the peaks 26 and 27, the bone fastening ring 60 is formed even if the fluid pressure of the lower part of the base 10 passes through the second peak 27. By reducing the pressure in the middle again it is possible to reduce the pressure burden applied to the first mountain (26).

Therefore, this embodiment can obtain a high pressure resistance effect as compared with the previous embodiment as well as the prior art.

For reference, the material of the bone fastening ring 60 is not necessarily limited to a metal material, and may be selectively applied as long as the material can be adhered to the fluid hole at a higher pressure by using a rubber material having a high hardness.

If the pressure member 50 is continuously rotated in this state, as shown in the previous embodiments, as shown in FIG. 9, the fixing ring 40 is expanded to close the front and rear movement of the stopper as the fluid hole P is in close contact with the wall.

At this time, because the bone fastening ring 60 is in close contact with the wall first than the fixing ring 40, as described above, the bone fastening ring 60 can play the role of the fixed ring 40 in advance.

Therefore, it is not necessary to use the fixing ring 40 in the fluid hole in which the relatively small pressure is formed.

In this case, the reason for dividing the pressing unit 30 into the first and second pressing plates 34 and 32 in the previous two embodiments is to install and press the fixing ring 40,

If there is no reason to divide the pressing plate by two if not provided with the fixing ring 40, as shown in FIG. 10, the first pressing plate 34 is provided with only the first pressing plate 34 as shown in FIG. ) Can be modified to form a direct pressurization.

That is, by providing the bone fastening ring 60, the second pressure plate 32 can be omitted as described above, so that the number and structure of parts can be much simpler.

FIG. 11 is an embodiment in which an expansion rubber ring is employed in a double manner.

That is, in the embodiment of FIG. 11, the configuration of the pressing portion is modified as follows.

That is, the expansion rubber ring 20 positioned below the second pressure plate 32 is not directly placed on the seating surface of the base portion 10, and the third pressure plate 36 and the second expansion rubber ring 21 are interposed therebetween. Inserted, the expansion rubber ring 20 is placed on the upper portion of the third pressure plate 36, the second expansion rubber ring 21 is placed on the seating surface of the base portion 10 and the lower portion of the third pressure plate (36) Is configured to contact.

In this case, both the expansion rubber ring 20 and the second expansion rubber ring 21 may use an expansion rubber ring having a ridge and a valley, but any one of them uses a conventional circular cross-section expansion rubber ring. It is okay.

In addition, both of the bone portion of the expansion rubber ring 20 and the second expansion rubber ring 21 may be provided with a bone fastening ring 60, may be provided only in either one.

In addition, when the fixing ring 40 is provided between the first pressing plate 34 and the second pressing plate 32, as shown in FIG. 11, the expansion rubber ring 20 and the second expansion rubber ring 21 It is possible to be carried out in the form of not having all the bone fastening ring 60 in the bone portion of.

According to the modified example of FIG. 11, the effect of reducing the number of components cannot be obtained as compared with the prior art, but a strong sealing effect can be obtained, and thus, the present invention can be applied to a fluid hole requiring high pressure in comparison with the other embodiments.

Although various features of the present invention described above may be variously modified and combined by those skilled in the art, such modifications and combinations may be provided in a fluid hole stopper to secure airtightness by using an expansion rubber ring.

It is related to the structure and purpose of forming a valley and a hill on the outer edge of the expansion rubber ring so that each hill is in close contact with the fluid hole wall, with the valley between them. If any, it should be determined that it belongs to the protection scope of the present invention.

1 is a cross-sectional view of a conventional pipe stopper installed

2 to 6b are views related to the first embodiment of the present invention.

2 is an exploded perspective view of the first embodiment

Figure 3 is an exploded perspective view of the first embodiment of Figure 2 of the present invention

3 is a perspective view showing a coupled state of FIG.

Figure 4 is a view showing a state before pressurization in a state installed in the fluid hole

Figure 5 is a cross-sectional view showing that the expansion rubber ring is expanded when pressurized so that each mountain portion is in close contact with the fluid hole wall

Figure 6a is a view showing a state in which the fixing ring is expanded in the pressing process

Figure 6b is a view showing an embodiment in which the number of valleys and peaks of the expansion rubber ring increased

7 to 9 are diagrams showing a second embodiment of the present invention.

Figure 7 is a cross-sectional view showing that the bone fastening ring is added in the valley of the expansion rubber ring

8 is a view showing that the bone fastening ring is in close contact with the fluid hole wall during the expansion of the expansion rubber ring

9 is a view showing a state in which the fixing ring is expanded in the pressing process

10 is a view showing a third embodiment of the present invention showing a state in which the pressing unit is configured only by the first pressure plate;

11 is a view showing a fourth embodiment of the present invention.

Claims (9)

A base portion having a threaded portion formed at an upper center and a seating surface formed around the threaded portion, An expansion rubber ring seated on a seating surface of the base part; A pressing part located on the expansion rubber ring; Located on the pressing portion is composed of a pressing member screwed with the base portion, The expansion rubber ring has a plurality of valleys of a predetermined depth up and down along the outer circumference, and the top and bottom of the valley portion is formed with a peak, and when the expansion is in close contact with the fluid hole wall with each peak separated by the valley, Separate bone fastening ring is inserted into the bone, The surface of the bone fastening ring is a fluid hole closure plug, characterized in that the concave-convex process. delete delete The method of claim 1, The pressurizing portion includes a second pressure plate seated on the expansion rubber ring; Consists of the first pressure plate laminated on the second pressure plate, A fixing ring is provided between each pressurizing plate, and the fixing ring is extended when the first pressurizing plate is pressurized to be in close contact with the fluid hole wall. delete delete The method of claim 4, wherein The surface of the fixing ring is a fluid hole closure stopper, characterized in that the irregular processing. delete delete

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