JP2020101289A - Reinforcement jig attachment method - Google Patents

Abstract

To provide a reinforcement jig attachment method which can attain desired fastening torque.SOLUTION: A reinforcement jig P includes: a first pressing part 6e which presses an outer surface 1a of a first flange part 1A in which a head of a connection bolt or a nut 4B is disposed; a second pressing part 5e which presses an outer surface 1a as seen in a joint direction of a second flange part 1B; and a fastening mechanism 7 which moves the first pressing part 6e and the second pressing part 5e close to each other in the joint direction to fix the pressing parts 6e and 5e. An attachment method of the reinforcement jig P includes: a first fastening step in which the fastening mechanism 7 is fastened; and a second fastening step in which the connection bolt or the nut 4B is fastened. The first fastening step is performed and then the second fastening step is performed.SELECTED DRAWING: Figure 6

Description

TECHNICAL FIELD The present invention relates to a method of mounting a reinforcing jig for reinforcing a joint portion between flange portions that project radially outward from ends of both tubular members.

As the above-mentioned reinforcing jig, for example, in Patent Document 1, a pair of clamping members each having a pressing portion that individually abuts a pair of flange joint portions, and a fastening mechanism that pulls and fixes both clamping members in the joint direction of the joint portions. A configuration including and is disclosed.

In addition, a C-shaped drop-prevention arm that contacts the head or nut of the connecting bolt that connects both flanges from the inside toward the outside in the radial direction is formed on one of the sandwiching members. The fall prevention arm prevents the reinforcing jig from dropping from both flange portions.

JP, 2014-141995, A

For example, when a flange joint of a water pipe bridge exposed on the ground is reinforced with a reinforcing jig, it is necessary to satisfy a desired tightening torque.

Therefore, a method of mounting a reinforcing jig that can obtain a desired tightening torque is desired.

The characteristic configuration of the mounting method of the reinforcing jig is that the first flange portion protruding radially outward from the end portion of the first cylindrical member and the second flange portion protruding radially outward from the end portion of the second cylindrical member. A method of mounting a reinforcing jig on a joint portion in which a connecting bolt and a connecting bolt are joined together, wherein the reinforcing jig includes a head of the connecting bolt or a nut of the first flange portion on which the nut is arranged. A first pressing portion that presses the outer side surface in the joining direction, a second pressing portion that presses the outer side surface of the second flange portion, the first pressing portion and the second pressing portion are close to each other in the joining direction. And a fastening mechanism for fixing the fastening mechanism, wherein the mounting method includes a first fastening step of fastening the fastening mechanism and a second fastening step of fastening the connecting bolt or the nut, The second fastening step is performed after the first fastening step is performed.

In this configuration, when the fastening mechanism is tightened when the reinforcing jig is fixed to the flange joint portion, the first flange portion and the second flange portion move toward each other due to the fastening force of the fastening mechanism. As a result, the connecting bolt or nut can be further tightened, and the tightening torque for the flange joint can be increased. A desired tightening torque can be obtained by tightening the fastening mechanism and the connecting bolt or the nut.

Another characteristic configuration is that the first fastening step and the second fastening step are alternately executed a plurality of times.

By alternately tightening the fastening mechanism and the connecting bolts or nuts as in this configuration, it is possible to reliably obtain a desired tightening torque.

Another characteristic configuration is that the center of the first pressing portion and the second pressing portion is a virtual annular surface formed by extending the outer shape of the head of the connecting bolt or the nut in the circumferential direction of the first tubular member. It is located in the area.

By tightening the fastening mechanism like this configuration, it is easy to form a gap between the head portion or nut of the connecting bolt and both flange portions, and the head portion or nut of the connecting bolt is attached to both flange portions. There is no inconvenience of one-sided contact. For this reason, when the connecting bolt or nut is tightened, both flange portions can be uniformly moved closer to each other.

It is an exploded perspective view of both cylindrical members. It is a top view of both cylindrical members. It is a longitudinal cross-sectional view of both tubular members. It is a figure which shows schematic structure of the 1st clamping member which concerns on 1st embodiment. It is a figure which shows schematic structure of the 2nd clamping member which concerns on 1st embodiment. It is a perspective view which shows the mounting state of the reinforcement jig which concerns on 1st embodiment. It is a top view which shows the mounting state of the reinforcement jig which concerns on 1st embodiment. It is a side view which shows the mounting state of the reinforcing jig which concerns on 1st embodiment. It is sectional drawing which shows the mounting state of the reinforcing jig which concerns on 1st embodiment. It is a top view of the reinforcement jig concerning a first embodiment. It is a front view of the reinforcement jig concerning a first embodiment. It is a right side view of the reinforcing jig which concerns on 1st embodiment. It is a rear view of the reinforcing jig which concerns on 1st embodiment. It is a left side view of the reinforcement jig concerning a first embodiment. It is a bottom view of the reinforcement jig concerning a first embodiment. It is an enlarged view which shows the 1st modification of 1st embodiment. It is an enlarged view showing the 2nd modification of a 1st embodiment. It is an enlarged view showing a third modification of the first embodiment. It is an enlarged view showing the 4th modification of a first embodiment. It is an enlarged plan view showing a mounted state of a reinforcing jig according to a second embodiment. It is an expanded side view which shows the mounting state of the reinforcement jig which concerns on 2nd embodiment. It is a perspective view which shows the mounting state of the reinforcement jig which concerns on another embodiment 1. It is a longitudinal cross-sectional view showing a mounted state of a reinforcing jig according to another embodiment 1. It is a longitudinal cross-sectional view showing a mounted state of a reinforcing jig according to another embodiment 2.

Hereinafter, an embodiment of a reinforcing jig P for a joint portion according to the present invention will be described with reference to the drawings. In the present embodiment, as an example of the reinforcing jig P, both flange portions 1A and 1B (radially outwardly protruding from the ends of the water pipes 1 and 1 (an example of the first tubular member and the second tubular member) ( A case of reinforcing the joint portion of the first flange portion and the second flange portion) will be described. However, the present invention is not limited to the following embodiments, and various modifications can be made without departing from the spirit of the invention.

1 to 3 show a flange joint part in the middle of a fluid piping system (pipe line). Both flange portions 1A and 1B formed in a disk shape projecting radially outward from the end portions of both cast iron water pipes 1 and 1, which are an example of a fluid pipe, respectively include a plurality of connecting bolts 4A and nuts 4B ( In the present embodiment, they are connected by eight places). In this embodiment, the side where the nut 4B is located is the first flange portion 1A, and the side where the head 4a of the connecting bolt 4A is located is the second flange portion 1B. Washers 4C and 4C are interposed between the nut 4B and the first flange portion 1A and between the head portion 4a of the connecting bolt 4A and the second flange portion 1B, respectively. In this way, the connecting bolt 4A, the nut 4B, and the washers 4C, 4C form a connecting mechanism for connecting the flange portions 1A, 1B. The washers 4C and 4C may be omitted.

A ring-shaped sheet-shaped gasket 2 is interposed between the flange portions 1A and 1B. A plurality of through holes 3 (in the present embodiment, 8 places each) penetrating in the flange joining direction (axial direction, hereinafter referred to as “joining direction”) are formed in both flange portions 1A and 1B at equal intervals in the circumferential direction. The connecting bolt 4A is formed through these through holes 3, and the nut 4B is screwed and fixed to the tip end side of the male screw portion 4b of the connecting bolt 4A. Both the flange portions 1A and 1B of the present embodiment are so-called RF type flanges having a flat seat surface inside the through hole 3.

Below, in both flange parts 1A and 1B, the surfaces on the side where the water pipe 1 projects are referred to as outer surfaces 1a and 1a in the joining direction. Further, the outer surfaces in the radial direction of 1A and 1B of both flange portions will be described as outer peripheral surfaces 1c and 1c.

As shown in FIGS. 4 to 6 and 9, the reinforcing jig P includes a first holding member 6 having a first pressing portion 6e that presses the outer surface 1a of the first flange portion 1A, and a second flange portion 1B. And a second holding member 5 having a second pressing portion 5e that presses the outer side surface 1a. These pressing parts 6e, 5e are formed on the outer surfaces 1a, 1a of the flange parts 1A, 1B by forming fine unevenness or by sticking a rubber member on the surfaces of the pressing parts 6e, 5e. Friction processing is performed so that frictional resistance is generated. It should be noted that both pressing portions 6e and 5e may not be subjected to friction processing, and the mode of friction processing is not particularly limited.

Further, with both pressing portions 6e, 5e abutting on the outer side surfaces 1a, 1a of the flange portions 1A, 1B, respectively, both clamping members 6, 5 (both pressing portions 6e, 5e) are pulled in the joining direction ( A fastening mechanism 7 for fixing (closely) is provided.

As shown in FIG. 4, the first holding member 6 is made of a metal member, and has an inserted portion 6A in which the outer surface 6a and the inner surface 6b are formed in a rectangular bottomed rectangular tube shape in a cross-sectional view, and the inserted portion 6A. A first base portion 6B (an example of a base portion) that extends outward from one of the four sides of the outer surface 6a of the inserted portion 6A and has a first pressing portion 6e at one end of the portion 6A, and a first base portion 6B. The fall prevention arm 6C extending from the side surface is integrally provided. The drop-out prevention arm 6C may be formed so as to extend from the tip end surface of the first base portion 6B, or the drop-off prevention arm 6C may be separately manufactured and joined to the first base portion 6B, and there is no particular limitation.

The inserted portion 6A is formed in a square shape in a side view (see the perspective view of FIG. 4), and inside the inserted portion 6A, a tubular inside for receiving the insertion portion 5A of the second holding member 5 along the joining direction. A space 6c is formed. That is, as shown in FIG. 6, when the reinforcing jig P is attached to both the flange portions 1A and 1B, a second holding member described later is provided at a position radially outside of the outer peripheral surface 1c of the first flange portion 1A. An insertion portion 5A is formed on the first holding member 6 and an insertion portion 6A that receives the insertion portion 5A inside is formed on the first holding member 6 along the joining direction.

The cylindrical internal space 6c is formed in a square shape in a cross sectional view, and is slightly larger than the square insertion portion 5A in a cross sectional view. Therefore, the shape perpendicular to the joining direction of the outer surface 5a of the insertion portion 5A and the inner surface 6b of the inserted portion 6A is such that when the insertion portion 5A is inserted into the tubular internal space 6c of the inserted portion 6A, the insertion direction (cylindrical It is slidable in the longitudinal direction of the internal space 6c, but is formed so as not to be capable of relative rotation around the insertion direction (around the axis along the longitudinal direction of the tubular internal space 6c).

Further, in the cylindrical internal space 6c, an opening is formed on the side opposite to the side on which the first base portion 6B is formed, and on the side on which the first base portion 6B is formed, the male screw portion 7a of the fastening bolt 7A can be inserted. Further, the insertion hole 6d that cannot be inserted through the head portion 7b is formed so as to penetrate the bottom portion of the inserted portion 6A (see the cross-sectional view of FIG. 4). When the male screw portion 7a of the fastening bolt 7A is inserted in the insertion hole 6d, a predetermined gap is formed between the outer peripheral surface of the male screw portion 7a and the inner peripheral surface of the insertion hole 6d ( (See FIG. 9).

The first base portion 6B is formed in a slightly constricted shape in a side view (see FIG. 4 plan view), and the side opposite to the side on which the first pressing portion 6e is formed inclines toward the tip side in a longitudinal sectional view. It is formed in a tapered shape (see the cross-sectional view in FIG. 4). Further, the tip portion of the surface of the first base portion 6B opposite to the insertion hole 6d is formed as a first pressing portion 6e perpendicular to the outer surface 6a of the inserted portion 6A. That is, the first base portion 6B has a function of supporting the first pressing portion 6e.

The fall prevention arm 6C is an L-shaped or C-shaped member that is formed to extend from the side surface of the first base portion 6B (see FIG. 4 plan view and FIG. 4 perspective view), and is a nut screwed to the connecting bolt 4A. 4B has a larger diameter than the outer circumference of the nut 4B so that at least a part of 4B can be surrounded. When the reinforcing jig P is attached to both the flange portions 1A and 1B, the drop-off preventing arm 6C comes into contact with the nut 4B from the inner side toward the radially outer side (see FIG. 6). Further, in the vertical cross-sectional view, of the surfaces forming the cap 6C, the surface on the side opposite to the insertion hole 6d in the longitudinal direction of the cylindrical internal space 6c has a gap with respect to the first flange portion 1A during mounting. As it has, it is formed so as to be retracted closer to the insertion hole 6d side than the first pressing portion 6e (see the cross-sectional view of FIG. 4). The first holding member 6 and the second holding member 5 may be mounted opposite to each other, and the cap 4C of the connecting bolt 4A may be brought into contact with the cap 6C, which is not particularly limited.

As shown in FIGS. 7 to 8, the cap 6C has at least a thickness of the edge portion 6Ca that abuts on the nut 4B so as to retract in the joining direction (toward the first flange portion 1A) with respect to the nut 4B. It is set smaller than other parts. Particularly, in the edge portion 6Ca of the cap 6C of the present embodiment, the stepped portion 6Cc that is stepped down toward the first flange portion 1A extends from the connecting portion between the first base 6B and the cap 6C to the tip portion 6Cb. It is formed over. That is, the edge portion 6Ca is formed with a notch having an L-shaped cross section inward in the radial direction so that the edge portion 6Ca is retracted toward the first flange portion 1A from the top surface 6Cd of the cap 6C. The notch of the edge portion 6Ca is set to a size such that a tightening tool (not shown) such as a ratchet or spanner for tightening the nut 4B can be inserted. If such a step portion 6Cc (notch) is formed, a concave gap is formed between the side surface of the nut 4B and the side wall of the step portion 6Cc, so that the tightening tool can be easily inserted and the tightening tool It is easy to hook the tip on the nut 4B.

The edge portion 6Ca is formed in an arc shape and is in point contact with the apex of the hexagonal nut 4B. The edge 6Ca may be brought into surface contact with the washer 4C, or the nut 4B may be formed in an arc shape so that the edge 6Ca is brought into surface contact, and there is no particular limitation. Further, the nut 4B may be formed in a polygonal shape other than the hexagon, and the edge portion 6Ca may be formed in a shape along the outer shape of the nut 4B.

As a result, even if the two flange portions 1A and 1B are distorted or deformed or are relatively displaced due to their own weight or an earthquake, the cap 6C reliably comes into contact with the nut 4B. It is possible to more reliably prevent the flanges 1A and 1B from falling off.

As shown in FIG. 5, the second holding member 5 is made of a metal material, and has an insertion portion 5A formed in a bottomed rectangular tube shape having a quadrangular outer surface 5a and a circular inner peripheral surface 5b in a cross-sectional view. And a collar-shaped portion 5B extending outward from the outer surface 5a of the insertion portion 5A over the entire circumference at one end of the insertion portion 5A, and further outward from one of the four sides of the collar-shaped portion 5B. It is configured to integrally include the extending second base portion 5C.

The insertion portion 5A is formed in a square shape in a side view (see FIG. 5 perspective view), and has a cylindrical shape into which the male screw portion 7a of the fastening bolt 7A of the fastening mechanism 7 described later can be inserted. A cylindrical internal space 5c is formed. The inner diameter of the cylindrical inner space 5c is formed to be slightly larger than the outer diameter of the male screw portion 7a of the fastening bolt 7A.

The collar-shaped portion 5B is formed in a square shape in a side view, and a cylindrical internal space 5c is formed in the central portion thereof so as to penetrate therethrough (see the cross-sectional view of FIG. 5).

In the cylindrical internal space 5c, an opening is formed on the side on which the collar-shaped portion 5B and the second base portion 5C are formed, and on the side opposite to the side on which the collar-shaped portion 5B and the second base portion 5C are formed, the fastening bolt 7A A female screw portion 5d to which the male screw portion 7a can be screwed is formed so as to penetrate the bottom portion of the insertion portion 5A. That is, the female screw portion 5d is formed on the inner peripheral surface 5b of the cylindrical inner space 5c in the insertion portion 5A at the end opposite to the side where the collar-shaped portion 5B and the second base portion 5C are formed. ..

The second base portion 5C is formed in a slightly constricted shape in a side view (see the plan view of FIG. 5), and is formed in a tapered shape that is inclined toward the female screw portion 5d as it goes to the distal end side in a longitudinal sectional view. (See FIG. 5 cross section). Further, the tip portion of the surface of the second base portion 5C on the female screw portion 5d side is formed as a second pressing portion 5e perpendicular to the outer surface 5a of the insertion portion 5A.

As shown in FIGS. 6 and 9, the fastening mechanism 7 includes a fastening bolt 7A that is inserted into the tubular internal space 6c from the outside of the inserted portion 6A through the insertion hole 6d, and the inner peripheral surface of the insertion portion 5A. 5b, and a washer 7B interposed between the fastening bolt 7A and the collar-shaped portion 5B. The washer 7B between the fastening bolt 7A and the collar-shaped portion 5B may be omitted.

Six-sided views of the above-described reinforcing jig P are shown in FIGS. 10 to 15. In addition, in the six-sided view of the reinforcing jig P, the insertion portion 5A of the second holding member 5 is inserted into the insertion portion 6A of the first holding member 6 without the joint portion between the flange portions 1A and 1B. , The state of being fixed by the fastening mechanism 7 is shown.

A feature of the reinforcing jig P in the present embodiment is that the fall prevention arm 6C has a stepped portion 6Cc formed on the edge portion 6Ca of the inner peripheral surface from the first base portion 6B to the tip portion 6Cb. is there. The fall-off preventing arm 6C contacts the head 4a of the connecting bolt 4A of the flanges 1A and 1B or the nut 4B screwed to the connecting bolt 4A to prevent the reinforcing jig P from falling off. The cap 6C of the present embodiment may be replaced with caps 61C, 62C, and 63C of modified examples described later. In this case, only the shape of the fall prevention arm 6C is changed to a hexagonal view, and detailed drawings are omitted.

Next, a work process of mounting the reinforcing jig P on both flange portions 1A and 1B connected by the plurality of connecting bolts 4A and nuts 4B will be described.

First, as shown in FIGS. 1 to 3, one of the existing bolts and nuts (not shown) of both flange portions 1A and 1B is removed and replaced with connecting bolts 4A and nuts 4B. Repeat this replacement for all existing bolts and nuts. At this time, in this embodiment, since the cap 6C has a thin edge portion 6Ca as an insertion space for the tightening tool, the connecting bolts 4A and the nuts 4B are composed of bolts and high nuts corresponding to high nuts. You don't have to. As a result, it becomes possible to use ordinary bolts and nuts, and thus the device cost can be saved.

Next, as shown in FIG. 6, the insertion portion 5A of the second holding member 5 is inserted into the first holding member 6 at a position radially outward of the outer peripheral surfaces 1c and 1c of the flange portions 1A and 1B. The insertion portion 6A is inserted into the cylindrical internal space 6c from the joining direction. At that time, since the outer surface 5a of the insertion portion 5A and the inner surface 6b of the inserted portion 6A are formed in a square shape that is relatively non-rotatable in a cross-sectional view, the first pressing portion 6e of the first holding member 6 and the second pressing portion 6e. The second pressing portion 5e of the holding member 5 can be easily inserted in a state where the second pressing portion 5e and the second pressing portion 5e are aligned in the desired relative positional relationship in the same direction.

Next, the fastening bolt 7A is inserted into the cylindrical internal space 6c from the outside of the inserted portion 6A in the joining direction through the insertion hole 6d and temporarily fixed. The engagement between the insertion portion 5A and the insertion portion 6A and the temporary fixing of the fastening bolt 7A are performed once in the joining direction by the first pressing portion 6e of the first holding member 6 and the second pressing portion of the second holding member 5. The distance to 5e is set to be slightly larger than the distance to the outer surface 1a of the first flange portion 1A and the outer surface 1a of the second flange portion 1B. That is, the size (insertion distance) of the overlapping portion between the inserted portion 6A and the inserting portion 5A in the joining direction and the interval between the first pressing portion 6e and the second pressing portion 5e can be set appropriately. .. Therefore, even when the wall thickness is changed according to the nominal diameter of both flange portions 1A and 1B or the design pressure, the size of the overlapping portion is adjusted, so that the first holding member 6 and the second holding member 5 can be adjusted. It can be satisfactorily fastened and fixed to both flange portions 1A and 1B.

Subsequently, the reinforcing jig P is attached to both the flange portions 1A and 1B. At this time, the outer surface 6a of the inserted portion 6A on the side where the first pressing portion 6e extends is brought into partial contact with at least one of the outer peripheral surfaces 1c, 1c of the flange portions 1A, 1B from the radially outer side. Further, the drop-off preventing arm 6C of the first holding member 6 is brought into contact with or close to the nut 4B in the radially outward direction from the inside (see FIG. 7).

The extending direction of the cap 6C is set to be the same as the direction in which the first holding member 6 provided with the cap 6C rotates together when the fastening bolt 7A is rotated to the tightening side. There is. In other words, the falling prevention arm 6C is tightened in the tightening direction of the fastening bolt 7A from the side surface of the first base portion 6B of the first holding member 6 (in the present embodiment, the fastening bolt 7A is a right-hand screw, and therefore the insertion hole 6d is centered). It is formed so as to extend in the clockwise direction). Therefore, when the fastening bolt 7A is tightened, the drop-out preventing arm 6C comes into contact with the nut 4B and becomes a rotation resistance, so that the tightening work is easy.

If there is no space to insert the fall prevention arm 6C inside the nut 4B in the radial direction, the reinforcing jig P may be mounted upside down. In this case, the fall prevention arm 6C abuts or approaches the head 4a of the connecting bolt 4A located on the second flange portion 1B from the inside in the radial outward direction.

Next, the first pressing portion 6e of the first holding member 6 presses the outer side surface 1a of the first flange portion 1A, and the second pressing portion 5e of the second holding member 5 is the outer side surface 1a of the second flange portion 1B. The fastening bolt 7A is tightened until is pressed, and the insertion portion 5A and the insertion portion 6A are pulled in the joining direction. As a result, the reinforcing jig P rotates in the clockwise direction, and the drop prevention arm 6C and the nut 4B are surely brought into contact with each other.

After mounting the reinforcing jig P, similarly, another reinforcing jig P is sequentially mounted from the radially outer direction to the other nuts 4B in both the flange portions 1A and 1B. In the present embodiment, the nuts 4B to be mounted by the reinforcing jig P are mounted at a total of 6 positions in which a set of 3 positions out of 8 positions is symmetrical with respect to the center of the first flange portion 1A. The reinforcing jig P may be attached to all the nuts 4B as necessary, or may be attached only to a part of a portion between the nuts 4B adjacent to each other.

Next, the male screw portion 7a of the fastening bolt 7A is screwed into the female screw portion 5d of the insertion portion 5A to tighten the fastening mechanism 7 of all the reinforcing jigs P (first fastening step). At this time, the fastening bolt 7A is located radially outside the both flange portions 1A and 1B, so that the tightening work is easy. Moreover, since the fall prevention arm 6C is in contact with the nut 4B, the tightening posture is stable.

When the fastening bolt 7A is tightened and fixed, the pressing portions 6e and 5e of the sandwiching members 6 and 5 move close to each other while being in contact with the outer surfaces 1a and 1a of the flange portions 1A and 1B. At the same time, the first flange portion 1A and the second flange portion 1B move toward each other by the tightening force of the fastening bolt 7A. As a result, the nut 4B can be further tightened.

Further, in the state where the reinforcing jig P is fixed to both the flange portions 1A and 1B, the centers of the first pressing portion 6e and the second pressing portion 5e are imaginary annular surfaces formed by extending the outer shape of the nut 4B in the circumferential direction. It will be located in the area of. Therefore, the first pressing portion 6e and the second pressing portion 5e move close to each other, so that a constant gap is easily formed between the nut 4B and the first flange portion 1A, and the nut 4B moves toward the first flange portion 1A. On the other hand, there is no inconvenience of a one-sided contact. For this reason, when the nut 4B is tightened, both flange portions 1A and 1B move uniformly closer to each other.

Next, tightening is performed on all the nuts 4B joining the flanges 1A and 1B with a tightening tool such as a ratchet or spanner (second tightening step). At this time, the connecting bolt 4A is fixed by using another tool such as a spanner.

In the present embodiment, the step portion 6Cc that is stepped down toward the first flange portion 1A so that the edge portion 6Ca of the drop-out prevention arm 6C retracts in the joining direction with respect to the nut 4B is a tip portion from the first base portion 6B. It is formed over 6 Cb (see FIG. 8). That is, around the nut 4B, the height of the cap 6C is set smaller than the height of the nut 4B. Therefore, when tightening the nut 4B, the tightening tool can be reliably inserted around the nut 4B.

Then, the tightening torque of the connecting bolt 4A, the nut 4B, and the fastening bolt 7A is alternately tightened until the tightening torque reaches a predetermined reference value (for example, 90 N·m at a nominal diameter of 250 mm). .. As a result, it is possible to further improve the joint strength of the flanges 1A and 1B by the reinforcing jig P, and to more reliably prevent the separation and displacement of the flanges 1A and 1B and the accompanying leakage of clean water. It is also possible to improve the seismic performance of pipelines.

As shown in FIG. 9, in the present embodiment, in addition to the fastening portion of the fastening mechanism 7, there is an overlapping portion of the insertion portion 5A and the inserted portion 6A. Therefore, when a shearing force that displaces the flange portions 1A and 1B in the radial direction acts, or a tensile force that pulls the flange portions 1A and 1B apart in the axial direction acts, the both pressing members 6 and 5 are pressed. Even when the portions 6e, 5e receive a force in the opening direction, it is possible to reduce the stress applied to the fastening portion of the fastening mechanism 7.

In the present embodiment, the female screw portion 5d is located at the overlapping portion of the insertion portion 5A and the insertion portion 6A in the cylindrical internal spaces 5c and 6c, so that the length of the fastening bolt 7A is relatively short. It becomes possible. Therefore, it is possible to favorably prevent the tip of the fastening bolt 7A from protruding to the outside of the cylindrical internal spaces 5c and 6c. Moreover, when the male screw portion 7a of the fastening bolt 7A is inserted in the insertion hole 6d, a predetermined gap is formed between the outer peripheral surface of the male screw portion 7a and the inner peripheral surface of the insertion hole 6d. Therefore, even if a force in the shearing direction (radial direction) acts on both flange portions 1A and 1B and the fastening bolt 7A is slightly displaced in the radial direction, the male screw portion 7a of the fastening bolt 7A is inserted into the insertion hole. It is possible to prevent the fastening bolt 7A from extending and breaking without coming into contact with the 6d.

As shown in FIG. 8, in the present embodiment, the surface of the fall prevention arm 6C that faces the outer surface 1a of the first flange portion 1A is separated from the outer surface 1a of the first flange portion 1A more than the first pressing portion 6e. Since it is arranged on the side where the fastening bolt 7A is tightened, the fall prevention arm 6C does not come into contact with the outer side surface 1a of the first flange portion 1A. As a result, the load is not directly applied to the cap 6C, and the cap 6C can be prevented from being damaged.

Further, even when the flange portions 1A and 1B are distorted or deformed or are relatively displaced due to their own weight or an earthquake or the like, the fall prevention arm 6C surely abuts the nut 4B. It is possible to more reliably prevent the flanges 1A and 1B from falling off. Similarly, even when the reinforcing jig P is provided at any position in the circumferential direction of both flange portions 1A and 1B, it is possible to prevent the reinforcing jig P from falling off from both flange portions downward. ..

Hereinafter, with respect to another embodiment, only a configuration different from the above-described embodiment will be described. To facilitate understanding of the drawings, the same members will be described using the same names and reference numerals.

[First Modification of First Embodiment]
In the edge portion 6Ca of the fall prevention arm 6C in the above-described embodiment, a step portion 6Cc that is stepped down toward the first flange portion 1A is formed from the first base portion 6B of the first holding member 6 to the tip portion 6Cb. did. Instead of this, as shown in FIG. 16, a stepped portion 61Cc that is stepped down toward the first flange portion 1A may be formed only on the periphery of the nut 4B at the edge portion 61Ca of the captive prevention arm 61C. .. In this case, since the thickness of the fall prevention arm 6C is secured from the first base portion 6B of the first holding member 6 to the portion where the step 61Cc is formed, the rigidity of the fall prevention arm 6C can be increased.

[Second Modification of First Embodiment]
As shown in FIG. 17, on the stepped portion 6Cc of the cap 6C, the tapered surface 6Ce is inclined from the first base portion 6B of the first holding member 6 to the tip portion 6Cb toward the first flange portion 1A. May be formed. As a result, the tightening tool for the nut 4B can be guided by the tapered surface 6Ce, so that the work for obtaining the desired tightening torque becomes extremely easy. The tapered surface 6Ce may be formed in a part of the stepped portion 6Cc so as to have a stepped shape other than the tapered surface 6Ce, or may be formed only around the nut 4B as in the above-described first modification. It is not particularly limited.

[Third Modification of First Embodiment]
As shown in FIG. 18, a taper surface 62Cc may be formed from the top surface 62Cd of the fall prevention arm 62C to the edge portion 62Ca. Even in this case, the tightening work of the nut 4B becomes easy. The first modification and the third modification may be combined.

[Fourth Modification of First Embodiment]
As shown in FIG. 19, the drop-out prevention arm 63C may be set to have a smaller thickness as it goes from the first base portion 6B of the first holding member 6 toward the distal end portion 63Cb of the drop-out prevention arm 63C. Even in this case, at least the edge portion 63Ca of the fall prevention arm 63C that comes into contact with the nut 4B is set to have a smaller thickness than other portions. For this reason, while facilitating the tightening work of the nut 4B, it is possible to secure sufficient thickness in the support portion (the connection portion with the first base portion 6B) of the drop-out prevention arm 63C and increase the rigidity. Moreover, since the thickness may be gradually reduced from the first base portion 6B toward the tip portion 63Cb, the processing is easy. The first modification, the second modification or the third modification may be combined with the fourth modification.

[Second embodiment]
In the above-described first embodiment, among the fall prevention arms 6C, 61C, 62C, 63C, at least the edge portions 6Ca, 61Ca, 62Ca, 63Ca that come into contact with the nut 4B are set to have a smaller thickness than other portions. Instead of this, as shown in FIGS. 20 to 21, the thick washer 4Ca (between the nut 4B and the outer surface 1a of the first flange portion 1A) so that the nut 4B is bulkier than the cap 64C. You may employ|adopt the reinforcement structure of the joining part which inserted the example of a height adjustment member. In this case, the top surface 64Cd can be formed on the same plane up to the edge 64Ca without making the thickness of the edge 64Ca of the drop-off prevention arm 64C smaller than that of other portions.

Even in the case of the present embodiment, the height of the fall prevention arm 64C is set to be smaller than the height of the nut 4B around the nut 4B. Therefore, when tightening the nut 4B, use a tightening tool around the nut 4B. It can be inserted securely. Moreover, since the edge portion 64Ca of the drop-preventing arm 64C comes into surface contact with the thick washer 4Ca, the posture of the drop-preventing arm 64C is easily stabilized. The thick washer 4Ca is not limited to an annular washer, but may be a coiled washer or a disc spring washer with a cut end, and is particularly a height adjusting member capable of withstanding a desired tightening torque. Not limited.

[Other Embodiment 1]
The configurations of the first holding member 6, the second holding member 5, and the fastening mechanism 7 in the above-described embodiment can be appropriately changed. For example, as shown in FIGS. 22 to 23, the second holding member 50 is configured by a U-shaped member including a pair of leg portions 50A and 50B, and the first holding member 60 is formed on the leg portion 50B. The bolt is provided with a male screw shaft portion 70a screwed into the through female screw hole 50a. The bolt serving as the first holding member 60 also functions as a fastening mechanism 70 that fixes the head portion 70b of the bolt and the second holding member 50 in close proximity to each other in the joining direction of the flange portions 1A and 1B. The first holding member 60 has a first pressing portion 60e that presses the first flange portion 1A, and the second holding member 50 presses the outer surface 1a of the second flange portion 1B against the tip portion of the leg portion 50A. The second pressing portion 50e is provided.

Also in the present embodiment, the fall prevention arm 6C is configured as an L-shaped or C-shaped member extending and formed from the side surface of the base portion 60B of the first pressing portion 60e (the base portion 60B supporting the first pressing portion 60e). Has been done. The step-preventing arm 6C has a stepped portion 6Cc that is stepped down toward the first flange portion 1A, and extends from the connecting portion between the first base 6B and the anti-dropping arm 6C to the tip 6Cb. Although the cap 6C is shown to have the same configuration as that of the first embodiment, the caps 61C, 62C, and 63C of the above-described modified examples and the reinforcing structure of the joint portion of the second embodiment are not shown. You may adopt it.

[Another embodiment 2]
As shown in FIG. 24, the insertion portion 51A of the second holding member 51 is formed into a square rod shape having an outer diameter that can be inserted into the insertion portion 61A of the first holding member 61, and the insertion portion of the first holding member 61 is inserted. The portion 61A has a tubular shape. Then, a bolt 52 having a male screw portion 52a is formed to project in the joining direction on the tip side of the insertion portion 51A, and the fastening nut is engaged in the inserted portion 61A in a relatively non-rotatable manner. The configuration may be such that 53 is screwed from the outside of the inserted portion 61A until it abuts on the outer surface side. Note that, also in this embodiment, the structure of the fall prevention arms 6C, 61C, 62C, 63C in the above-described embodiment and the reinforcing structure of the joint portion in the second embodiment are adopted.

[Other Embodiments]
(A) In the above embodiment, the two flange portions 1A and 1B are connected by the eight pairs of connecting bolts 4A and nuts 4B. However, depending on the nominal diameter and design pressure of the flange portions 1A and 1B, the connecting bolts The numbers of 4A and nuts 4B can be adjusted appropriately.

(B) The procedure for mounting the reinforcing jig P can be changed as appropriate. For example, first, the first pressing portion 6e of the first holding member 6 is brought into contact with the outer surface 1a of the first flange portion 1A, and the cap 6C is attached to the nut 4B from the radially inner side of the first flange portion 1A. Contact or approach. Next, the insertion portion 5A of the second holding member 5 is inserted into the insertion portion 6A from the joining direction, and the second pressing portion 5e is brought into contact with the outer side surface 1a of the second flange portion 1B. Next, the male screw portion 7a of the fastening bolt 7A is screwed into the female screw portion 5d of the insertion portion 5A through the insertion hole 6d of the inserted portion 6A, and both clamping members 6 and 5 are attached to both flange portions 1A and 1B. You can also do it.

(C) In the above-described embodiment, the fall prevention arm 6C is provided only on the first holding member 6, but it may be provided on the second holding member 5 or both holding members 6 and 5 if necessary. Further, the drop-off prevention arm 6C is not simply formed in a concave shape that wraps around the head portion 4a of the connecting bolt 4A or the nut 4B from the radially inner side of both flange portions 1A and 1B to the radially outer side. Alternatively, the flange portions 1A and 1B may be configured by rod-shaped members that come into contact with each other from the radially inner side.

(D) In the above-described embodiment, the first holding member 6 is provided with the inserted portion 6A and the second holding member 5 is provided with the insertion portion 5A. However, the second holding member 5 is provided with the inserted portion. The first holding member 6 may be provided with an insertion portion.

(E) In the above-described embodiment, the insertion portion 5A of the second holding member 5 and the inserted portion 6A of the first holding member 6 have a square shape, but relative rotation around the joining direction is impossible. Any shape may be used as long as it is provided. For example, the shape of the outer surface 5a of the insertion portion 5A and the inner surface 6b of the insertion portion 6A can be configured in an elliptical shape, a polygonal shape, or the like in a cross-sectional view.

(F) In the above-described embodiment, the configuration in which both flange portions 1A and 1B are so-called RF type flanges has been described, but other flange joints may be used as long as they are flange joints, for example, groove portions for gaskets. It may be a so-called GF type flange provided with.

(G) In the above embodiment, the reinforcing jig P is attached to both flange portions 1A and 1B formed in both cast iron water pipes 1 and 1, which are an example of a fluid pipe that constitutes a fluid piping system (pipe line). Although an example has been described, the fluid pipe may be a pipe through which gas or liquid flows.

INDUSTRIAL APPLICABILITY The joint jig and the reinforcing structure according to the present invention can be used as a jig for reinforcing pipes, fluid devices, or a joint between a fluid device and a pipe.

1 Water pipe (first tubular member, second tubular member)
1A 1st flange part 1B 2nd flange part 1a Outer side surface 4A Connecting bolt 4a Head part 4B Nut 4Ca Thick washer (height adjusting member)
5e 2nd press part 6e 1st press part 6B 1st base (base)
6C Fall prevention arm 6Ca Edge 6Cc Step 6Ce Tapered surface 63Cb Tip 7 Fastening mechanism P Reinforcing jig

Claims (3)

Reinforcing the joint portion where the first flange portion projecting radially outward from the end portion of the first tubular member and the second flange portion projecting radially outward from the end portion of the second tubular member are joined with a connecting bolt. A method of mounting a reinforcing jig for mounting a jig,
The reinforcing jig is
A first pressing portion that presses the outer surface in the joining direction of the first flange portion in which the head or nut of the connecting bolt is arranged,
A second pressing portion that presses the outer surface of the second flange portion,
A fastening mechanism that fixes the first pressing portion and the second pressing portion in the joining direction so as to be close to each other,
The mounting method is
A first fastening step of fastening the fastening mechanism,
A second fastening step of fastening the connecting bolt or the nut,
A method of mounting a reinforcing jig, wherein the second fastening step is performed after the first fastening step is performed. The method for mounting a reinforcing jig according to claim 1, wherein the first fastening step and the second fastening step are alternately performed a plurality of times. The centers of the first pressing portion and the second pressing portion are located within an area of an imaginary toroidal surface obtained by extending the outer shape of the head of the connecting bolt or the nut in the circumferential direction of the first tubular member. The method for mounting a reinforcing jig according to claim 1 or 2, wherein.

Images