JP2678735B2 - Connection structure between metal flexible tube and other tube - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a metallic flexible tube connecting structure including a bellows formed in a corrugated shape.

[0002]

2. Description of the Related Art Conventionally, for example, for various industrial equipment pipes, relative displacement between each equipment connected by the pipes and equipment (for example, displacement due to ground subsidence, displacement due to machine motion, or installation position error) A hose or expansion joint is used to absorb misalignment.

Therefore, in recent years, while ensuring corrosion resistance,
A flexible metal tube is used, which is highly flexible and flexible, and is capable of absorbing slight displacement in the longitudinal direction and temperature shrinkage, and the outer peripheral surface of a stainless steel bellows is also covered with a stainless steel blade. In order to connect this flexible metal tube to another pipe body, as shown in FIG. 10, a split ring is fitted to the corrugated surface of the bellows, and this split ring is attached to the flange of the other pipe body with an annular flange. A connection structure for connecting while pressing is widely used because of its excellent workability.

[0004]

However, in the above-described metal flexible tube connection structure, the split ring fitted in the valley portion of the corrugated surface of the bellows has a thickness width which is equal to the width of the valley portion of the bellows. Due to the limitation, it is difficult to increase the thickness, and as shown in FIG. 11, the split ring is deformed in an inclined shape in a sectional view in the direction in which it is pressed by the annular flange, so that the packing cannot be pressed uniformly, and the connecting portion There was a problem that the watertightness of the product deteriorated and a leak accident occurred.

The present invention has been made in view of the above problems of the prior art, and an object thereof is to provide a split ring when a metallic flexible tube is connected to another tubular body while being pressed by an annular flange. Provided is a connection structure between a metal flexible tube and another tube body that can prevent deformation and can improve the watertightness by evenly contacting the end of the bellows of the metal flexible tube with another tube body. To do.

[0006]

To achieve the above object, the present invention provides a flexible metal tube 16 including a bellows 14 having a corrugated surface on which corrugations 12 are continuously formed, and another tubular body 1.
8, a corrugation 12 that is substantially the same as the corrugation 12 of the bellows 14 is formed on the inner peripheral surface, and a split ring 24 having the inner peripheral surface fitted to the outer peripheral surface of the bellows 14, and the split ring 24. An annular flange 26 for engaging the ring 24 and pressing against the other tubular body 18 to be connected.
4, the bellows 1 with respect to the other tubular body 18 to be connected.
It is composed of a connection structure 10 for connecting a flexible metal tube formed by uniformly crimping 4 and another tube body.

Further, the split ring 24 is provided with valley portions 30, 30 on both sides of at least one corrugated portion 12 of the bellows 14.
It may be formed integrally from the to the mountain portion 32 with a U-shaped cross section.

A blade 28 is attached to the outer surfaces of the bellows 14 and the split ring 24, and another tubular body 18 to be connected to the split ring 24 by engaging the annular flange 26 from the outer surface side thereof. It may be configured to be pressed to.

Next, the present invention provides a metal flexible tube 16 including a bellows 14 having a corrugated surface on which corrugations 12 are continuously formed.
The bellows 14 at the connection portion between the bellows 14 and the other tubular body 18.
Of at least two sets of split rings 2 which are arranged in the valleys 30 adjacent to each other of the corrugations 12 and whose outer peripheral sides can come into close contact with each other.
4-1 and 24-2, and the split rings 24-1 and 24
-2, is provided with an annular flange 26 for pressing against another tube body 18 to be connected, and further, the split ring 24-
1 and 24-2 are composed of a connecting structure 10 for connecting a flexible tube made of metal, which is provided with an escape portion 52 for accommodating and accommodating the corrugated portion 12 of the bellows 14, with another tubular body.

An annular holding plate 56 is sandwiched between the two sets of split rings 24-1 and 24-2 adjacent to each other, and the annular holding plate 56 has split rings 24- on both sides thereof.
Engagers 60 that engage with the split ends 54, 54 of 1, 24-2
It may be configured to include a and 60b.

The engaging elements 60a and 60b are arranged with a phase difference from each other corresponding to the positions of the split ends 54 and 54 of the split rings 24-1 and 24-2. Good.

Further, the bellows 14 and the split ring 24-
Blades 28 are attached to the outer surfaces of the first and the second 24-2.
-1, 24-2 may be engaged and pressed to another tube body 18 to be connected.

Next, the present invention provides a metallic flexible tube 16 including a bellows 14 having a corrugated surface on which corrugations 12 are continuously formed.
The bellows 14 at the connection portion between the bellows 14 and the other tubular body 18.
Outer split ring 24-3 arranged in the valley portion 30 of one corrugation 12 so as to sandwich at least one corrugated side wall 62 of the corrugation 12, and the bellows 1 facing the valley portion 30.
4 and an inner split ring 24-4 arranged on the inner surface side,
It is composed of a connecting structure 10 between a flexible metal tube and another tubular body, which is attached to the outer split ring 24-3 and has an annular flange 26 for pressing against the other tubular body 18 to be connected. It

In the inner split ring 24-4 and the outer split ring 24-3, the inner split ring 24-4 and the outer split ring 24-3 are alternately arranged from the side closer to the other pipe 18 to be connected. It may be configured as follows.

The bellows 14 and the split ring 24-
A blade 28 is attached to the outer surface of each of 3, 24-4.
-3, 24-4 may be engaged and pressed to another tube body 18 to be connected.

[0016]

In the connection structure of the flexible metal tube and the other tubular body according to the first embodiment of the present invention, the corrugated end portion of the bellows of the flexible metal tube is left over, and the second waveform is added. A split ring that is split in two is fitted to the ridge portion and the valley portions on both sides of the corrugation, and the blade is attached to the outer peripheral surface. Then, slide the annular flange communicating with the metal flexible tube to the split ring side, attach the annular flange to the split ring, and then tighten the annular flange to the flange of the tubular body with a fastener. The split ring is pressed against the tubular body. As a result, the corrugation of the end of the rose of the metal flexible tube is in a state in which it is doubly bent and comes into close contact with the packing attached to the end surface of the tubular body in a squeezed state. The width and thickness of the corrugations that extend from the crests of the two corrugations to the troughs on both sides are large, increasing its strength and rigidity, and without deforming when pressed by the annular flange, the bellows at the ends. Is evenly pressed against the packing of the pipe body to improve the watertightness of the connection surface.

Next, in the connecting structure of the metallic flexible tube of the second embodiment and another tube body, the bellows has two end portions on the side of the end portion of the bellows and one on each side of the peak portion of the next corrugation. The first of the set,
A second split ring is arranged, the annular flange attached to the metal flexible tube is attached to the first and second split rings, and the annular flange of the end portion of the bellows is fastened while tightening the annular flange to the flange of another pipe body. The corrugated shape is squeezed into close contact with the packing of the other tubular body, and the corrugated shape sandwiched in the first and second split rings is squeezed and accommodated in one of the escape portions. As a result, the thickness of the split ring is increased by the joined first and second split rings to increase the rigidity, and the split ring is prevented from being deformed when it is tightened to the flange of another pipe body to prevent the end portion of the bellows from being deformed. The watertightness can be improved while evenly adhering to the packing. First,
It is also possible to prevent the weakening or deformation of the rigidity of the split ring while disposing the split end at a phase difference by engaging the engaging element of the annular holding plate on the split end of the second split ring. .

Next, in the connecting structure of the metallic flexible tube of the third embodiment and another tubular body, at least one corrugated side wall of the corrugated shape on the end side of the bellows is sandwiched between the corrugated corrugated walls. An outer split ring arranged in the valley portion and an inner split ring arranged on the inner surface side of the bellows facing the valley portion are provided, and an annular flange is attached to the outer split flange and tightened to the flange of another pipe body. It is a thing. The inner split ring and the outer split ring arranged on the inner and outer surfaces of the corrugated side wall of the bellows do not cause rattling in the adjacent state, and the ends of the bellows are evenly aligned with the packing of the pipe body while maintaining a uniform joint state. It is possible to improve the watertightness between the end of the bellows and the packing. The inner split ring and the outer split ring are arranged such that the inner split ring and the outer split ring are alternately arranged from the side closer to the other pipe to be connected, and the inner split ring and the outer split ring are stacked. The number of mating pieces may be selected and arranged to increase the thickness of the split ring as a whole to increase rigidity, prevent deformation of the split ring, and improve the watertightness of the connection surface between the bellows and packing. Becomes Further, in each of the above-described embodiments, the outer surface of the bellows and the split ring is covered with a blade, and the annular flange is attached to the split ring to press against another tube body, so that the blade is firmly and stably held. And damage can be prevented.

[0019]

Preferred embodiments of the present invention will be described below with reference to the accompanying drawings. FIG. 1 shows a first embodiment of a connection structure (hereinafter, abbreviated as a metal flexible tube connection structure) 10 for connecting a metal flexible tube and another tube body according to the present invention. As is apparent from the drawing, the flexible tube connection structure 10 made of metal according to the first embodiment.
In the connecting portion between the metal flexible tube 16 including the bellows 14 having the corrugated surface in which the corrugated surface 12 is continuously formed, and the other tubular body 18, the inner peripheral surface has substantially the same corrugation as the corrugated surface 12 of the bellows 14. 20 and a split ring 24 in which the inner circumferential surface 20 is fitted to the outer circumferential surface 22 of the bellows 14, and for engaging with the split ring 24 and pressing against another tube body 18 to be connected. And an annular flange 26.

As shown in FIG. 1, a metallic flexible tube 16 comprises a stainless steel bellows 14 in which corrugations 12 are continuously formed.
A stainless steel metal wire or a blade 28 formed by braiding thin strips is attached to the outer surface of the blade. The bellows 14 has a substantially hollow cylindrical structure, and the surface thereof is pleated to form a corrugated corrugated section 12 and is configured to maintain watertightness. Further, the braided blade 28 is attached to the outer surface thereof. As a result, the metal flexible tube 16
Can be installed in a piping position that is highly flexible and flexible and requires a centering work in piping work and a large bending portion, and can simplify and speed up the construction.

As shown in FIGS. 1 and 3, the split ring 24 is
A half ring 24 made of steel cast iron, hard synthetic resin or the like and divided into two so as to be fitted to the outer peripheral surface of the bellows 14.
a and 24b. This half ring 24a,
24b is a circumferential groove 34 in the central portion of the inner circumferential surface 20, and a circumferential groove 34 in the center portion of the inner circumferential surface 20 so that the valley portions 30, 30 of the at least one corrugation 12 of the bellows 14 can be closely attached to the crest portion 32.
Circumferential ridges 36, 36 are provided on both sides of the
Are integrally formed in a U-shaped cross section from the valley portions 30, 30 on both sides to the mountain portion 32.

Thus, the pair of half rings 24a, 2
The split ring 24 that joins 4b has a waveform 1 of the bellows 14.
It can be easily fitted to 2 and one corrugation of bellows 14
The thickness and width of the split crest 24 are increased so that the crests 24 of the second ring 32 fit into the troughs 30, 30 on both sides, so that the strength and rigidity of the split ring 24 are increased, and there is almost no deformation when pressed.
The watertightness of the connection surface 38 between the flexible metal tube 16 and the other tubular body 18 can be improved. That is, by forming the inner surface of the split ring substantially the same as the corrugation of the bellows, the effective thickness of the split ring can be increased, and the portion entering the valley portion of the bellows becomes a strength member that resists the conical deformation of the split ring. Therefore, the strength and rigidity of the ring are increased, and the ring is hardly deformed to form a good sealing surface.

The annular flange 26 for pressing the split ring 24 against the other tubular body 18 is made of steel cast iron, hard synthetic resin or the like as the split ring 24 and is thick enough to communicate with the metal flexible tube 16. Is formed into an annular body. This annular flange 26
Is provided with a circumferential groove 40, which is notched so as to engage with the outer peripheral edge of the split ring 24, at one edge of the inner peripheral surface thereof, and is further connected to a flange 42 of another tubular body 18 to be connected. A plurality of tightening holes 44 for engaging the tightening tools such as bolts with each other are opened. Bellows 14 on the outer surface of the split ring 24
The blade 28 is adhered to the annular flange 26, and the annular flange 26 is fastened to the other tubular body 18, so that the blade 28 can be firmly and stably held and the bellows 14 and the like can be prevented from being damaged. The annular flange 26
Is the annular flange 26 without the circumferential groove 40.
The side surface of the ring may be directly joined to the side surface of the split ring 24.

Next, the operation of the metal flexible tube connection structure 10 according to the first embodiment of the present invention will be described. When the metal flexible tube 16 is connected to the tube body 18 made of another metal or the like at a work site or the like, the annular flange 26 is provided on the outer peripheral surface of the blade 28 on the end side of the metal flexible tube 16. The blade 28 is made to pass through, and the blade 28 is peeled off in a curl shape to expose the end portion of the bellows 14.

Waveform 1 at the end of the exposed bellows 14
The half ring 24 that divides the two into the peak portion 32 of the second corrugation 12 and the valley portions 30 and 30 on both sides by leaving 2 apart
The a and 24b are fitted, for example, in the vertical direction, and the split ring 24 is again attached to the outer peripheral surface of the blade 28 that has been peeled off in the above-mentioned turning shape. The number of peaks at the end of the waveform 12 is not limited to one, and may be a plurality of rows. Then, the annular flange 26 that has been engaged is slid to the split ring 24 side, and the circumferential step groove 40 of the annular flange 26 is attached to the edge of the split ring 24.

Then, as shown in FIG. 1, the annular flange 2
6 and a plurality of tightening holes 44, 44 formed in the flange 42 of the tubular body 18, by inserting a tightening tool 46 such as a bolt into the tightening holes 44, 44, and sliding the annular flange 26 toward the flange 42. 24 is pressed against the tubular body 18.

As a result, the corrugation 12 at the end of the bellows 14 which is in sliding contact with the packing 48 mounted on the end face of the tubular body 18 is in a double-folded state and compressed into the packing 48. In close contact. The split ring 24 has a single waveform 12.
Since the width and thickness extending from the crest 32 to the troughs 30, 30 on both sides are formed to be large, the strength and rigidity thereof are increased, and the end is not deformed when pressed by the annular flange 26. The packing 48 is evenly pressed by the squeezed corrugated portion 12 to dramatically improve the watertightness of the connection surface 38.

Next, FIGS. 4 and 5 show a second embodiment of the metal flexible tube connection structure 10 according to the present invention. In the second embodiment, since the configurations of the metal flexible tube 16, the annular flange 26, and the other tubular body 18 are the same as those in the first embodiment, the same members are designated by the same reference numerals and detailed description thereof is omitted. The description is omitted. In the second embodiment, the metal flexible tube 1
6, the bellows 14 of the corrugated 12 corrugated 12 adjacent to each other,
0, and at least two sets of a first split ring 24-1 and a second split ring 2 which can be in close contact with each other on their outer peripheral sides.
4-2 and.

The inner surfaces of the first split ring 24-1 and the second split ring 24-2 are formed on the arcuate surface 50 in cross section so that they can fit into the valleys 30 of the bellows 14. Further, on the abutment surface of the first split ring 24-1 and the second split ring 24-2 that are adjacent to each other, one of the two split rings has one of the bellows 14 extending from the intermediate position to the lower end. An escape portion 52 for accommodating and accommodating two corrugations 12 is provided. The relief portion 52 has the corrugated portion 12 of the bellows 14 in the first and second portions.
While being sandwiched by the split rings 24-1 and 24-2, it is recessed so as to accommodate the squeezed waveform 12. As a result, one corrugation 12 can be smoothly sandwiched between the first split ring 24-1 and the second split ring 24-2, and their side surfaces can be brought into close contact with each other.

Further, as shown in FIG. 6, for example, the first split ring 24-1 has the split halves 24a and 24b arranged vertically, and the second split ring 24-2 has the split halves 24a and 24a.
24b are arranged on the left and right, and the split ends 54, 54 of the first split ring 24-1 and the split ends 54 of the second split ring 24-2,
54 and 54 are arranged with a phase difference of approximately 90 degrees and joined.

As a result, one waveform 1 of the bellows 14
2 is sandwiched between the first split ring 24-1 and the second split ring 24-2, and the annular flange 26 is fastened to the second split ring 24-2 and tightened to the flange 42 of the other tubular body 18. Further, the positions of the split ends 54, 54 of the first and second split rings 24-1, 24-2, which have low rigidity, can be mutually reinforced, and the corrugations 12 at the ends of the bellows 14 by the split rings can be pressed uniformly. .

Since the corrugations 12 of the bellows 14 can be sandwiched by providing the relief portions 52 shown in FIG. 4 on the side surfaces of the first and second split rings, the wall thickness can be increased while joining the first and second split rings. It is possible to increase the rigidity of the split ring and increase the rigidity of the split ring to prevent deformation when tightening the split ring to the flange 42 of another tubular body 18, thereby improving the watertightness of the tubular body 18 and the metal flexible tube 16.
In addition, in the present embodiment, two sets of the first and second split rings are joined, but the present invention is not limited to this, and three sets of the first, second and third split rings may be joined, In this case, the split ends of the first, second and third split rings are arranged with a phase difference of approximately 60 degrees from each other.

An annular holding plate 56 as shown in FIG. 7 is sandwiched between the joint surfaces of the first split ring 24-1 and the second split ring 24-2 which are adjacent to each other. This annular holding plate 56
Is made of a thin metal plate, and is made of the first and second split rings 24.
−1, 24-2, an annular plate 58 that can be joined to the peripheral side surfaces, and both sides of this annular plate 58 along the radial direction of the annular plate 56,
Each split end 5 of the first and second split rings 24-1 and 24-2
Engagements 60a, 60 fixed on both sides of the annular plate 58 with a phase difference of approximately 90 degrees from each other so as to be engaged with the Nos. 4 and 54.
b.

The annular holding plate 56 is sandwiched between the first and second split rings, and the engaging elements 60a and 60b on both surfaces thereof are respectively engaged with the split ends 54 of the first and second split rings to form a half split. It is possible to prevent weakening and deformation of the rigidity of the split ring formed by arranging the split ends 54, 54 of the respective first and second split rings arranged in a cross shape with each other and joining them.

Next, the operation of the metal flexible tube connection structure 10 according to the second embodiment of the present invention will be described. In the present embodiment, as shown in FIG. 4 and FIG. 5, the following waveform 1 except for one waveform 12 is provided on the end side of the bellows 14 of the metallic flexible tube 16.
The first and second split rings 24-1 and 2 are provided on both sides of the second mountain portion 32.
4-2 is arranged, the annular holding plate 56 is further sandwiched between the first and second split rings, and the blade 28 is attached to the outer peripheral surface.

Then, the annular flange 26 attached to the flexible tube 16 made of metal is attached to the first and second split rings, and the annular flange 26 is tightened to the flange 42 of the other tubular body 18 while the bellows 14 of the bellows 14 is being tightened. The corrugations 12 at the ends are pressed into close contact with the packing 48 of the flange 42, and the corrugations 12 sandwiched between the first and second split rings are compressed and accommodated in one of the escape portions 52.

As a result, the thickness of the split ring is increased by the joined first and second split rings 24-1 and 24-2 to increase the rigidity, and when tightened to the flange 42 of another tubular body 18. The watertightness can be improved while preventing the deformation of the split ring and evenly adhering the end portion of the bellows 14 to the packing 48.

Further, a blade 28 is attached from the bellows 14 to the first and second split rings 24-1 and 24-2, and an annular flange 26 is attached to the blade 28 so as to be fastened to another tube body 18. 28 can be firmly and stably held, and damage to the internal bellows 14 and the like can be prevented. Further, in the first and second split rings, the split ends 54, by engaging the engaging elements 60a, 60b of the annular holding plate 56 to the split ends of the respective half rings 24a, 24b.
It is possible to prevent weakening and deformation of the rigidity of the split ring while arranging 54 with a phase difference.

Next, FIGS. 8 and 9 show a third embodiment of the metal flexible tube connection structure 10 according to the present invention. Also in this third embodiment, since the configuration of the metal flexible tube 16, the annular flange 26, the other tubular body 18, etc. is the same as that of the first embodiment, the same members are designated by the same reference numerals, and the details thereof will be given. Detailed description is omitted.

In this third embodiment, the bellows 14
The outer split ring 24-3 arranged in the valley portion 30 of the corrugated 12 so as to sandwich at least one corrugated side wall 62 of the corrugated portion 12 on the end side of the corrugated portion 12, and the inner surface of the bellows 14 facing the valley portion 30. And an internal split ring 24-4 disposed on the side.

As shown in FIG. 8, the outer split ring 24-3.
Has an arcuate surface 64 formed on the inner peripheral surface thereof in the width-thickness direction so that it can be fitted in the valley portion 30 of the corrugated portion 12 of the bellows 14.
Similar to the first and second embodiments, the half ring is divided into two. Also, the internal split ring 24-4
Is a width thickness that can be fitted to the inner surface side of one corrugation 12 of the bellows 14, and arcuate surfaces 64, 64 are formed in the inner peripheral surface and the outer peripheral surface in the width direction, and are divided into two. It is formed into a half ring.

In FIG. 8, the inner split ring 24-4 is arranged on the inner peripheral surface of the corrugated portion 12 at the end of the bellows 14, and the outer split ring 2 is formed on the outer peripheral surface of the valley portion 30 adjacent to the corrugated portion 12.
4-3 are arranged, and the inner split ring and the outer split ring are evenly adhered to each other via the corrugated side wall 62 of the bellows 14.

Metal flexible tube connection structure 1 of the third embodiment
0, the outer split ring 24-4 is covered with the blade 28 from the bellows 14, and the outer split ring 24-4 is attached.
The annular flange 26 is fastened to the flange 42 of the other tubular body 18, and the corrugated side wall 62 of the bellows 14 is fastened.
The inner split ring and the outer split ring arranged on the inner and outer surfaces of the bellows 14 are evenly joined to each other without causing rattling in the adjoining state, and the ends of the bellows 14 are evenly aligned with the packing 48 of the tubular body 18. And the watertightness between the end of the bellows 14 and the packing 48 can be improved. Also, the blade 28
Can be firmly and stably held, and damage to the bellows 14 and the like can be prevented.

The inner split ring 24-4 and the outer split ring 24-3 are arranged alternately from the inner split ring 24-4 and the outer split ring 24-3 from the side closer to the other pipe 18 to be connected. As shown in FIG. 9, the inner split ring 24-4 and the outer split ring 24-3 may be selectively arranged in a plurality of overlapping numbers. It can be made larger to improve rigidity, prevent deformation of the split ring, and improve watertightness of the connection surface between the bellows and the packing.

As described above, the present invention provides a flexible metal tube 1
At the connecting portion between 6 and the other tubular body 18, the split ring that presses the bellows 14 of the metal flexible tube against the tubular body 18 can be prevented from being deformed, and the bellows 14 can evenly and closely contact the tubular body 18. The watertightness can be improved, and workability and workability can be improved by constructing the connection part of each industrial facility pipe, and the occurrence of leakage accidents at the connection part can be prevented.

[0046]

As described above, according to the connection structure of the metal flexible tube and the other tube body, the metal flexible tube including the bellows having the corrugated surface in which the corrugations are continuously formed and the other At the connecting portion with the tubular body, a corrugation substantially the same as the corrugation of the bellows is formed on the inner peripheral surface, and the split ring having the inner peripheral surface fitted to the outer peripheral surface of the bellows and the split ring engaged with the split ring. The annular ring for pressing against the other pipe body to be connected, and the bellows are evenly crimped to the other pipe body to be connected by the split ring. The thickness of the flexible tube does not deform when tightened to another tube, and the end of the bellows of the metal flexible tube is evenly adhered to the packing of the other tube, greatly improving watertightness. Can be done.

Further, since the split ring is integrally formed in a U-shaped cross section from both troughs to peaks of at least one corrugation of the bellows, the split ring has a high rigidity and an annular flange. The end portion of the bellows of the metal flexible tube can be evenly adhered to another tube body without causing tilt deformation when being pressed.

Further, a blade is attached to the outer surfaces of the bellows and the split ring, and the annular flange is attached to the split ring from the outer surface side and pressed against another pipe body to be connected. As a result, the blade can be firmly and stably held and damage to the bellows or the like can be prevented.

Next, according to the connection structure of the metallic flexible tube and the other tubular body, the metallic flexible tube including the bellows having the corrugated surface in which the corrugations are continuously formed is connected to the other tubular body. In the section, arranged in the valleys adjacent to each other in the corrugation of the bellows,
The outer peripheral side has at least two sets of split rings that can come into close contact with each other, and is provided with an annular flange that is engaged with this split ring and presses against another pipe body to be connected. By providing the relief portion for accommodating and accommodating the corrugated shape of the bellows, the thickness of the two split rings joined together increases, and the split ends of the split split rings are crossed with a phase difference. Parts with weak rigidity can be replenished with each other, and the corrugated parts of the bellows sandwiched by the split ring can be stacked while accommodating the corrugated part of the bellows in the relief part, improving the rigidity of the split ring. In addition, the end portion of the bellows can be evenly adhered to the pipe body without deformation of the split ring and the watertightness of the connection portion can be improved.

An annular holding plate is sandwiched between the two sets of split rings adjacent to each other, and the annular holding plate is
The split ends of the two sets of split rings are overlapped with each other while the engagement elements are attached to the split ends of the split rings on both sides thereof, while the split ends of the two sets of split rings are fastened with the engagers. Then
We can prevent weakening.

Further, since the engaging elements are arranged with a phase difference from each other corresponding to the position of the split end of the split ring, overlapping of split ends of the split ring can be prevented, The rigidity can be increased while stacking a plurality of split rings, and the watertightness of the connecting portion can be improved.

Further, a blade is attached to the outer surfaces of the bellows and the split ring, and the annular flange is attached to the split ring from the outer surface side and pressed against another pipe body to be connected. This makes it possible to firmly and stably hold the blade and prevent damage to the bellows and the like.

Next, according to the connection structure of the metallic flexible tube and the other tubular body, the metallic flexible tube including the bellows having the corrugated surface in which the corrugations are continuously formed is connected to the other tubular body. In the section, an outer split ring arranged in one trough of the corrugation so as to sandwich at least one corrugated side wall of the corrugation of the bellows, and an inner split ring arranged on the inner surface side of the bellows facing the trough. A ring, and an annular flange for engaging with the outer split ring and pressing against another pipe to be connected, so that the inner split ring and the outer split ring are connected via the corrugated side wall of the bellows. Therefore, the ends of the bellows can be evenly adhered to the pipe body while maintaining a uniform joint state without being loosened by being evenly adjacent to each other, and the watertightness of the connection part can be improved.

The inner split ring and the outer split ring are formed by alternately arranging the inner split ring and the outer split ring from the side closer to the other pipe to be connected. It is possible to increase the rigidity of the entire split ring by arranging a plurality of each of and, and to prevent deformation of the connection portion and improve watertightness.

Further, a blade is attached to the outer surfaces of the bellows and the split ring, and the annular flange is attached to the split ring from the outer surface side and pressed against another pipe body to be connected. This makes it possible to firmly and stably hold the blade and prevent damage to the bellows and the like.

[Brief description of the drawings]

FIG. 1 is a partially enlarged cross-sectional view of a connection structure between a metal flexible tube and another tube body according to a first embodiment of the present invention.

FIG. 2 is a view taken along the line AA of FIG. 1;

FIG. 3 is a perspective view of a split ring of the first embodiment.

FIG. 4 is a partially enlarged cross-sectional view of a connection structure between a metal flexible tube and another tube body according to the second embodiment.

FIG. 5 is an explanatory view of inserting the two sets of split rings into the corrugated troughs of the bellows according to the second embodiment.

FIG. 6 is a perspective view of two sets of split rings of the second embodiment.

FIG. 7 is a perspective view of an annular holding plate.

FIG. 8 is a partially enlarged cross-sectional view of a connection structure between a metal flexible tube and another tube body according to the third embodiment.

FIG. 9 is a partially enlarged cross-sectional view of an embodiment in which the number of inner and outer split rings of the connection structure between the flexible metal tube and another tubular body according to the third embodiment of FIG. 8 is increased.

FIG. 10 is a partially enlarged cross-sectional view of a conventional connecting structure of a metal flexible tube and another tube body.

11 is an explanatory view showing a state of a split ring deformed in the embodiment of FIG.

[Explanation of symbols]

 10 Connection structure between metal flexible tube and other tubular body 12 Corrugated 14 Bellows 16 Metal flexible tube 18 Tubular body 24 Split ring 24-1 10% ring 24-2 2nd split ring 24-3 External split Ring 24-4 Internal split ring 26 Annular flange 28 Blade 30 Valley part 32 Crest part 52 Escape part 54 Split end 56 Annular holding plate 60 Engager 62 Corrugated side wall

 ─────────────────────────────────────────────────── ─── Continuation of front page (72) Inventor Hiroaki Murata 272-1 Takao, Otsu-machi, Kikuchi-gun, Kumamoto Prefecture Tokyo Flex Kumamoto factory (56) References Flat 2-50016 (JP, U) Actual Open 63-171789 (JP, U) Actual Open 3-94492 (JP, U) Actual Open Flat 1-121788 (JP, U) Actual Public 3-53117 (JP , Y2)

Claims (5)

(57) [Claims] 1. A connecting portion between a metal flexible tube including a bellows having a corrugated surface in which corrugations are continuously formed and another tubular body, and a corrugation substantially the same as the corrugation of the bellows is formed on an inner peripheral surface. ,
A split ring whose inner peripheral surface to the outer peripheral surface of the bellows is fitted, and engaged with the split ring, and a annular flange for pressing the other pipe to be connected, the split ring , At least one corrugation of said bellows
Formed in a U-shaped cross section from the valley to the mountain on both sides of
Is, by the split ring, the connection structure between metallic flexible tube and another tube comprising evenly crimped the bellows to the other pipe to be connected. 2. A connecting portion between a metal flexible tube including a bellows having a corrugated surface in which corrugations are continuously formed and another tubular body, the corrugated portions of the bellows are arranged in adjacent troughs, and the outer peripheral side is disposed. At least two sets of split rings that can come into close contact with each other are provided, and the split ring is provided with an annular flange for pressing against other pipes to be connected. An escape portion for accommodating and corrugating is provided, and the escape portion is an abutting surface of the two sets of split rings.
The plate surface of the split ring is recessed so as to accommodate the corrugation.
A structure for connecting a flexible metal tube and another tubular body that are provided in the same manner . 3. An annular holding plate is sandwiched between two sets of the split rings adjacent to each other, and the annular holding plate has engaging elements on both sides thereof for engaging split ends of the split ring. A connecting structure between the flexible metal tube according to claim 2 and another tube body. 4. The flexible metal tube and another tubular body according to claim 3, wherein the engaging elements are arranged with a phase difference from each other corresponding to the position of the split end of the split ring. Connection structure with. 5. A blade is attached to the outer surfaces of the bellows and the split ring, and the annular flange is engaged with the split ring from the outer surface side thereof and pressed against another pipe body to be connected. A connection structure between the flexible metal tube according to any one of items 1 to 4 and another tube body.