JP7479763B2 - Flexible hose and manufacturing method thereof - Google Patents

Description

The present invention relates to a flexible hose. In particular, the present invention relates to a flexible hose in which a flexible strip is wound in a spiral shape and the side edges of the strip are crimped and joined with a metal reinforcing body.

Flexible hoses, which are made by spirally winding a flexible strip and crimping the side edges of the strip with a metal reinforcing member to form a cylindrical hose wall, are lightweight and are used for a variety of purposes, such as blowing air for air conditioning.

For example, Patent Document 1 discloses a technology for a stretchable flexible duct for air conditioning, in which a flexible strip having a metal foil layer and a synthetic resin layer is wound in a spiral shape, and the side edges of the flexible strip are crimped and joined with a spiral non-flammable reinforcing member to form a cylindrical duct. Patent Document 1 discloses that the flexible duct has excellent stretchability and ease of handling, and good heat resistance.

JP 2006-234188 A

As disclosed in Patent Document 1, a flexible hose in which a flexible strip is wound in a spiral shape and crimped and joined with a metal reinforcing member is lightweight and flexible. At the same time, it is expected that the airtightness of the flexible hose will be further improved. In the flexible hose of the prior art, the side edges of the flexible strip are crimped and joined with a metal strip, so the airtightness of the crimped and joined parts tends to be insufficient. In particular, when trying to improve the fire resistance and non-combustibility of the flexible strip, the material of the flexible strip tends to be poorly elastic, and the airtightness of the flexible hose is easily compromised.

An object of the present invention is to improve the airtightness of a flexible hose in which a flexible strip is spirally crimped and joined with a spiral reinforcement.

After extensive research, the inventor discovered that the airtightness of a flexible hose can be improved by forming the spiral reinforcement to which the flexible strip is crimped and joined into a reinforcement of a specific cross-sectional shape, and by sandwiching the overlapping portions of the flexible strip between the wire and the spiral reinforcement on both sides of the portion where the wire housed inside the spiral reinforcement is sandwiched approximately in the direction of the central axis of the hose so that they are in close contact with each other, thus completing the present invention.

The present invention is a flexible hose in which a flexible strip of a predetermined width is wound in a spiral shape, the side edges of adjacent flexible strips are overlapped with each other, and the overlapped portions are crimped and joined with a spiral reinforcement formed by folding a metal strip, and the spiral reinforcement has an Ω-shaped cross section in a plane including the central axis of the hose, and the Ω-shaped cross section has a hollow portion located on the outer periphery of the hose, a constricted portion connected to the inner periphery edge of the hollow portion, and an inner periphery located on the inner periphery of the hose and connected to the inner periphery edge of the constricted portion, and the constricted portion has a width smaller in the direction of the central axis of the hose than the hollow portion and the inner periphery, and the inner periphery is The flexible hose extends from the inner peripheral edge of the constriction in a direction along the central axis of the hose, and the hollow portion has a hollow shape with the inner peripheral side of the hose open and the outer peripheral side of the hose closed. In the flexible hose, the overlapping portion and the wire are housed inside the hollow portion of the spiral reinforcement, and the hollow portion of the spiral reinforcement is crimped with the overlapping portion arranged to encase the wire, and the overlapping portion of the flexible strip is sandwiched between the wire and the spiral reinforcement so as to be in close contact with each other on both sides of the portion where the wire is sandwiched approximately along the central axis of the hose (first invention).

In the first aspect of the present invention, the direction in which the narrowed portion and the hollow portion are aligned is inclined obliquely with respect to the radial direction of the hose .

The present invention also provides a method for producing the flexible hose of the first invention , which includes a step of helically winding the flexible strip, the helical reinforcement, and the wire while bending a metal strip to form the Ω-shaped cross section and accommodating the overlapped portion of the flexible strip and the wire in a hollow portion that is being formed, and a step of compressing and crimping the hollow portion in a direction to sandwich the wire substantially along the central axis of the hose as a final stage of the step or subsequent to the step.

According to the flexible hose of the present invention (first invention) and the method for manufacturing a flexible hose of the present invention ( second invention), the airtightness of the flexible hose is improved .

FIG. 2 is a partial cross-sectional view of the flexible hose of the first embodiment. 2 is a cross-sectional view of the spiral reinforcement of the flexible hose of the first embodiment. FIG. FIG. 2 is a cross-sectional view of a spiral reinforcement of the flexible hose of the first embodiment. 3A to 3C are cross-sectional views each showing a schematic diagram of a manufacturing process for the flexible hose of the first embodiment. 4A to 4C are diagrams illustrating schematic changes in cross section that occur when a reinforcing body is subjected to bending deformation. FIG. 11 is a cross-sectional view showing a modified example of a helical reinforcement body. FIG. 6 is a cross-sectional view showing a flexible hose according to a second embodiment.

The following describes an embodiment of the invention, taking as an example an air conditioning duct used in an air conditioning system for a house or the like, with reference to the drawings. The invention is not limited to the specific embodiment shown below, and can be practiced by modifying the form. In addition, the specific use of the flexible hose described below is not limited, and it can also be used for other purposes, such as an air conditioning duct for office air conditioning, a ventilation duct, an industrial ventilation duct, and a flexible hose for transporting liquids.

Figure 1 shows a partial cross-sectional view of a flexible hose 1 of the first embodiment. The upper half of the hose above the central axis m is shown as a cross-sectional view, and the lower half is shown as an external view. The flexible hose 1 has a hose wall 11 and a helical reinforcement 12. The hose wall 11 and the helical reinforcement 12 are integrated with each other.

The hose wall 11 is formed into a cylindrical shape by spirally winding a flexible strip T1 of a predetermined width and overlapping the side edges T1A, T1B of adjacent flexible strips T1. For example, the flexible strip T1 may be a flexible strip made of a woven fabric material with at least one side coated with a resin material and cut to a predetermined width. The flexible strip T1 may also be a flexible strip made of a sheet-like material made of a synthetic resin such as polyethylene resin or polyurethane resin cut to a predetermined width. The flexible strip T1 may have a laminated structure.

The woven fabric material constituting the flexible strip T1 is not particularly limited, but from the viewpoint of increasing the heat resistance, fire resistance, and non-combustibility of the hose, it is preferable that the woven fabric material is composed of fibers made of a non-combustible material. Examples of fibers made of a non-combustible material include glass fiber, silica fiber, and metal fiber. In addition, the resin material coating the woven fabric material is not particularly limited as long as it can adequately maintain the airtightness of the flexible strip, but from the viewpoint of increasing the heat resistance and fire resistance of the hose, it is preferable that it is a silicone resin (particularly silicone rubber) or a fluororesin (particularly fluororubber). From the viewpoint of increasing the heat resistance and fire resistance of the hose, it is particularly preferable that the flexible strip T1 is a flame-retardant flexible strip in which a woven fabric material composed of fibers made of a non-combustible material is coated with a silicone resin or a fluororesin.

The spiral reinforcement 12 is formed by bending a metal strip T2 into a predetermined cross-sectional shape and winding it into a spiral shape. Examples of metal materials constituting the metal strip T2 include, but are not limited to, thin iron or aluminum plates, galvanized steel plates, stainless steel plates, copper plates, brass plates, and the like.
The metal spiral reinforcement 12 is crimped so that the overlapping portions (hereinafter also referred to as "overlapped portions") of the side edges T1A, T1B of adjacent flexible strips T1 fit inside the spiral reinforcement 12, joining the side edges T1A, T1B of the flexible strips T1 to each other, thereby forming the cylindrical hose wall 11.

Figure 2 shows a cross-sectional view of the periphery of the spiral reinforcement 12 of the flexible hose 1 of the first embodiment, and the detailed structure will be described below. Figure 3 shows the cross-sectional shape of the spiral reinforcement 12. These cross-sections are cross-sections in a plane including the hose central axis m. In these figures, the lower side of the figure corresponds to the inner circumference side of the hose, and the upper side of the figure corresponds to the outer circumference side of the hose. In addition, the left and right directions of these figures correspond to the hose central axis direction, but for convenience, in the following description, the left side of the figure is called one end side of the hose central axis, and the right side of the figure is called the other end side of the hose central axis. The same applies to Figures 3 to 7. In addition, in Figure 2, in order to make the cross-section easier to see, the hatching is different between the side edge portion T1A on the other end side of the hose central axis of the flexible strip T1 and the side edge portion T1B on one end side of the hose central axis of the flexible strip T1. The same applies to Figure 7.

The spiral reinforcement 12 is formed by bending a metal strip T2 of a specified width so that the cross section in a plane including the hose central axis m has an Ω (ohm)-shaped cross section (Figure 3). Here, the Ω-shaped cross section refers to a cross section having a hollow portion 121 located on the outer periphery of the hose, an inner periphery 123 located on the inner periphery of the hose, and a narrowed portion 122 provided between the hollow portion 121 and the inner periphery 123, and in terms of the width in the hose central axis direction, the width W2 of the narrowed portion 122 is smaller than the width W1 of the hollow portion 121 (the width of the widest part) and the width W3 of the inner periphery 123 (the width of the widest part).

The hollow portion 121 has a hollow shape with the inner circumference of the hose open and the outer circumference of the hose closed. In the flexible hose 1, the overlapping portion of the flexible strip T1 and the wire 13 are housed inside the hollow portion 121 of the spiral reinforcement 12.

The hollow portion 121 of the spiral reinforcement 12 is crimped with the overlapping portion of the flexible strip T1 positioned inside the hollow portion 121 so as to encase the wire 13. Crimping makes it difficult for the side edge portions T1A, T1B of the flexible strip T1 to slip out of the hollow portion 121, maintaining the shape of the cylindrical hose wall 11. In addition, the width (W2) of the constriction portion 122 is made smaller than the width W1 of the hollow portion 121 in the hose axial direction, and this configuration reliably prevents the overlapping portion of the flexible strip T1 from slipping out of the hollow portion 121.

In addition, on both sides of the hollow portion 121 where the wire 13 is sandwiched in the direction of the hose's central axis, the overlapping portion of the flexible strip T1 is sandwiched between the wire 13 and the spiral reinforcement 12 so that they are in close contact with each other. With this configuration, the overlapping portion of the flexible strip T1 is pressed linearly and in close contact with each other, improving the airtightness of the hose.

Here, the wire 13 can be made of metal wire (aluminum wire, brass wire, copper wire, steel wire, iron wire, etc.), resin-coated metal wire (steel wire coated with hard polyvinyl chloride resin, etc.), resin wire (polypropylene resin wire, PET resin wire, polyvinyl chloride resin wire, etc.), etc., but is not limited to these. The wire 13 may be a paper string, twine, cord, braided wire, etc., as long as the overlapping portion of the flexible strip T1 can maintain a shape that is more expanded than the narrowing portion 122 inside the hollow portion 121 and the overlapping portion can be prevented from slipping out.

Although not required, in this embodiment, the hollow portion 121 is formed with a rectangular cross-sectional shape. In this embodiment, the hollow portion has a portion located on the outer periphery of the hose and extending along the hose axial direction, and a portion extending in a straight line approximately parallel to the hose radial direction. As in the modified example described below, the hollow portion 121 may be an open ring or an elliptical shape.

Although not essential, it is preferable, as in this embodiment, for the hollow portion 121 to be formed so that it is wider on the outer periphery of the hose, so that the overlapping portions of the side edges T1A, T1B of the flexible strip are clamped so as to be in close contact with each other, at least in the portion of the hollow portion 121 that is radially inward of the hose from the widest portion.

The constriction portion 122 is composed of a pair of parts facing each other. It is preferable that these parts extend in approximately the radial direction of the hose. The constriction portion 122 extends from the end of the hollow portion 121 on the inner circumference side of the hose toward the inside in the radial direction of the hose. Note that the extension direction of the constriction portion 122 does not have to strictly match the radial direction of the hose, and as in the embodiment described below, the extension direction of the constriction portion 122 may be inclined with respect to the radial direction of the hose.

Since the width W2 of the constricted portion 122 is smaller than the width W1 of the hollow portion 121, the portion of the hollow portion 121 on the inner circumference side of the hose is preferably provided with an inclined portion whose width gradually narrows toward the inner circumference side of the hose.

The spiral reinforcement 12 is further provided with inner peripheral portions 123, 123 extending from the inner peripheral edge of the narrowed portion 122 in a direction along the hose central axis m. Although not essential, a pair of inner peripheral portions may be provided as in this embodiment. That is, in the Ω-shaped cross section of the spiral reinforcement 12, a hollow portion 121 is provided on the outer peripheral side of the hose, and an inner peripheral portion 123 is provided on the inner peripheral side of the hose, and a narrowed portion 122 is provided to connect the hollow portion 121 and the inner peripheral portion 123. The Ω-shaped cross section has the narrowest width in the hose central axis direction at the narrowed portion 122.
The inner circumferential portion 123 may be provided for each of the pair of throttle portions 122 , or may be provided for only one of the pair of throttle portions 122 .

The flexible hose 1 of the above embodiment can be manufactured by a known hose manufacturing method, similar to the flexible hose described in Patent Document 1.

The flexible strip T1, the metal strip T2, the wire 13, etc. are prepared.
A hose manufacturing apparatus is also prepared. The hose manufacturing apparatus can bend the metal strip T2 to a predetermined cross section, give it a helical bent shape to form the helical reinforcement 12, and insert the side edge of the flexible strip T1 and the wire 13 into predetermined positions of the helical reinforcement 12, thereby crimping the helical reinforcement 12. Such hose manufacturing apparatus is publicly known.

The metal strip T2, flexible strip T1, and wire 13 are supplied to the hose manufacturing device, and with each component placed in a predetermined position, the spiral reinforcement 12 is formed and crimped to continuously manufacture the flexible hose 1 of the above embodiment. This manufacturing process includes the following two steps.

In the first step, the metal strip T2 is folded to have the Ω-shaped cross section, and the overlapping portion of the flexible strip T1 and the wire 13 are accommodated in the hollow portion 121 being formed, while the flexible strip T1, the spiral reinforcement 12, and the wire 13 are spirally wound. In this step, the metal strip T2 is gradually deformed to have the Ω-shaped cross section of the spiral reinforcement 12 while passing between a metal mold and a molding roller. Then, in synchronization with the deformation of the metal strip T2, the overlapping portions of the side edges T1A and T1B of the spirally wound flexible strip T1 are accommodated together with the wire 13 inside the hollow portion 121 of the spiral reinforcement. This process is shown in Figures 4(a) and 4(b).
Here, the length and position of the overlapping portion are adjusted so that when the overlapping portion and wire 13 are accommodated inside hollow portion 121 of the spiral reinforcement body, the overlapping portion is located on both sides of portions 13A and 13B which sandwich wire 13 approximately in the direction of the central axis of the hose.

The manufacturing process of the flexible hose of the above embodiment includes a second step as the final step of the first step or subsequent to the first step. In the second step, the hollow portion 121 is compressed and crimped in a direction in which the wire 13 is sandwiched approximately in the hose central axis direction (FIG. 4(c)). By going through this crimping process, in the flexible hose 1, the overlapping portions of the side edges T1A, T2B of the flexible strip T1 are sandwiched between the wire 13 and the spiral reinforcement 12 on both sides of the portion in which the wire 13 is sandwiched approximately in the hose central axis direction so that they are in close contact with each other. Note that the direction in which the hollow portion of the spiral reinforcement 12 is crimped does not have to strictly coincide with the direction of the hose central axis m, and the two may be inclined relative to each other.

The operation and effects of the flexible hose 1 of the above embodiment will be described.
In the flexible hose 1, the cross section of the spiral reinforcement 12 is an Ω-shaped cross section, which has a hollow portion 121 located on the outer periphery of the hose and a narrowed portion 122 located on the inner periphery of the hose, and the narrowed portion 122 has a smaller width in the hose central axis direction than the hollow portion 121. The overlapping portions of the side edges T1A, T1B of the flexible strip T1 and the wire 13 are accommodated in the hollow portion 121 and joined by crimping. This configuration ensures reliable joining of the side edges of the flexible strip T1, improving the strength and durability of the hose.

In addition, in the flexible hose 1 of the above embodiment, the Ω-shaped cross section of the spiral reinforcement 12 further has an inner peripheral portion 123 located on the inner periphery of the hose and connected to the inner peripheral edge of the narrowed portion, and the inner peripheral portion 123 extends in a direction along the central axis of the hose from the inner peripheral edge of the narrowed portion. In addition, on both sides of the portion (13A, 13B) where the wire 13 is sandwiched approximately along the central axis of the hose, the overlapping portions of the side edges T1A, T1B of the flexible strip T1 are sandwiched between the wire 13 and the spiral reinforcement 12 so as to be in close contact. With this configuration, the overlapping portions of the flexible strip are firmly pressurized by the wire 13 and the hollow portion 121 of the spiral reinforcement, so that the overlapping portions are in close contact and the sealing (airtightness) of the flexible hose is improved.

In a flexible hose having a spiral reinforcement body with an Ω-shaped cross section as in the above embodiment, the reason why the sealing performance is significantly improved by clamping the overlapping portions of the side edges T1A, T1B of the flexible strip T1 in close contact between the wire 13 and the spiral reinforcement body 12 on both sides (13A, 13B) of the portion where the wire 13 is clamped approximately along the central axis of the hose is as follows.

The metal strip T2 to become the spiral reinforcement 12 is originally a flat member wound in a coil and supplied, and its longitudinal length is the same no matter where it is measured in the width direction. When bending such a metal strip T2 to form an Ω-shaped cross section, if it is simply bent, the reinforcement formed will be linear. In the manufacturing process for a flexible hose, this reinforcement is deformed into a spiral shape to be integrated into the hose. In this case, in the form in which the reinforcement is arranged, the circumference is relatively long on the outer periphery of the hose and relatively short on the inner periphery of the hose. In order for the reinforcement to be arranged in a spiral shape, it is necessary for the reinforcement to deform in order to eliminate the gap between the inner and outer circumferences.

As a result, the cross-sectional deformation of the reinforcement 12 occurs such that the gap in circumferential length between the inner and outer circumferential sides becomes smaller, and the height of the reinforcement in the radial direction of the hose becomes smaller. This is shown in Figure 5. As in the above embodiment, when a reinforcement (Figure 5(a)) in which a wide hollow portion 121 is integrated with a narrow narrowed portion 122 and an inner circumferential portion 123 is bent into a spiral shape, a cross-sectional change occurs such that the height of the reinforcement becomes smaller, as shown in Figure 5(b).

As a result of this change in cross section, the distance d between the opposing constricted portions 122 (the distance between the constricted portions in the hose central axis direction) decreases. In conjunction with this deformation, the hollow portion 121 also deforms so that its width in the hose axial direction decreases. As a result, the hollow portion 121 is biased so as to firmly clamp the overlapping portions of the side edges of the flexible strip T1 and the wire 13 in the hose central axis direction.

In this way, when the hollow portion 121 of the spiral reinforcement 12 is biased, the overlapping portions of the flexible strip sandwiched between the wire 13 and the spiral reinforcement 12 come into tight contact with each other, and the overlapping portions of the side edges of the flexible strip T1 form a seal line along the wire 13, improving the sealing of that portion. As a result, the spirally wound flexible strip T1 becomes a cylindrical hose wall 11 with a linearly sealed joint, improving the sealing of the flexible hose 1. In addition, because the overlapping portions of the flexible strip are sandwiched between the wire 13 and the spiral reinforcement 12 on both sides of the portion where the wire 13 is sandwiched approximately along the hose central axis, a double seal is formed at two locations, improving the reliability of the seal.

Furthermore, by using the hose manufacturing method as in the above embodiment, a flexible hose as in the first embodiment can be efficiently obtained.

From the viewpoint of further improving the sealing performance of the hose, it is preferable that the hollow portion 121 of the Ω-shaped cross section of the spiral reinforcement 12 is rectangular, and that the width of the hollow portion increases from the portion that clamps the overlapping portion of the wire 13 and flexible strip along the hose axial direction toward the outer periphery of the hollow portion.

In addition, although it is not essential, as in this embodiment, when the overlapping portions are clamped so that they are in close contact with each other at least in the portion of the hollow portion 121 that is radially inward of the widest portion of the hose, the biasing force of the hollow portion 121 due to the above-mentioned action works more strongly, further improving the sealing performance.

In addition, although not essential, it is preferable that the flexible strip T1 is a flame-retardant flexible strip made of a woven fabric material made of fibers made of a non-flammable material coated with silicone resin or fluororesin. If the flexible hose of the above embodiment is constructed using such a flexible strip, a flexible hose with excellent heat resistance and improved sealing properties can be obtained.

The invention is not limited to the above-described embodiment, and can be implemented with various modifications. Other embodiments of the invention are described below, but in the following description, the differences from the above-described embodiment will be mainly described, and detailed descriptions of similar parts will be omitted. Furthermore, these embodiments can be implemented by combining parts with each other, or by substituting parts.

In the above description of the first embodiment, an example was described in which the inner peripheral portions 123 of the Ω-shaped cross section of the spiral reinforcement are provided in pairs with approximately the same length, but the inner peripheral portions 123 may be provided only on one side, or only on one end side or only on the other end side in the central axis direction of the hose. An example of such a spiral reinforcement 22 is shown in Fig. 6. The spiral reinforcement 22 in Fig. 6 differs from the first embodiment in that the hollow portion 221 is elliptical and one of the inner peripheral portions 223 connected to the inner peripheral edge of the narrowed portion 222 is longer than the other, but is otherwise similar.
The use of such a spiral reinforcement 22 can also improve the sealing performance of the hose.

Furthermore, if the spiral reinforcement is given an asymmetric cross section like the spiral reinforcement 22 of the second embodiment in Figure 6, it becomes easier to make the direction X-X in which the constricted portion 222 and hollow portion 221 are aligned inclined obliquely with respect to the hose radial direction (the up-down direction in Figure 7) as shown in Figure 7. In a flexible hose, if the direction X-X in which the constricted portion 222 and hollow portion 221 are aligned is inclined obliquely with respect to the hose radial direction, a stronger bias acts in the direction (Y-Y) in which the hollow portion of the spiral reinforcement is crimped to make the hollow portion narrower. This further improves the sealing properties of the hose.

The direction of the mold for forming the spiral reinforcement may be tilted so that the X-X direction in which the narrowed portion 222 and hollow portion 221 are aligned is inclined obliquely to the radial direction of the hose, but by providing the inner periphery 223 on only one side, or by making one of the inner periphery 223 longer than the other, the spiral reinforcement can be tilted so that the hollow portion 221 falls toward the side where the inner periphery is shorter or where there is no inner periphery.

The flexible hose 1 of the above embodiment may have other members or layers, such as a heat insulating layer or a protective layer. In addition, another hose or tube may be placed inside the flexible hose 1 of the above embodiment, and the flexible hose 1 of the above embodiment may be used as a sheath member or protective member.

The flexible hose 1 of the above embodiment can be used, for example, in air conditioning ducts and ventilation ducts that require heat resistance. The flexible hose 1 of the above embodiment may also be used for transporting liquids. The flexible hose 1 of the above embodiment can also be used as a heat-resistant cover for pipelines, wiring, etc.

The flexible hose 1 of the above embodiment can be used in air conditioning ducts, has good sealing properties, and is highly useful in industry.

REFERENCE SIGNS LIST 1 Flexible hose 11 Hose wall T1 Flexible strips T1A, T1B Side edge portion 12 Spiral reinforcement body T2 Metal strip 121 Hollow portion 122 Constricted portion 123 Inner circumference portion 13 Wire rod

Claims (2)

A flexible strip of a predetermined width is spirally wound, and the side edges of adjacent flexible strips are overlapped with each other;
A flexible hose in which the overlapping portions are crimped and joined by a spiral reinforcement body formed by bending a metal strip,
The helical reinforcement has an Ω-shaped cross section in a plane including the hose central axis,
the Ω-shaped cross section has a hollow portion located on the outer periphery of the hose, a constricted portion connected to an inner periphery edge of the hollow portion, and an inner periphery portion located on the inner periphery of the hose and connected to an inner periphery edge of the constricted portion,
The narrowed portion has a width in the hose central axis direction smaller than those of the hollow portion and the inner circumferential portion,
The inner peripheral portion extends from an inner peripheral edge of the constricted portion in a direction along a central axis of the hose,
The hollow portion has a hollow shape in which the inner peripheral side of the hose is open and the outer peripheral side of the hose is closed,
In the flexible hose, the overlapping portion and the wire are housed inside the hollow portion of the spiral reinforcement body,
the hollow portion of the spiral reinforcement body is crimped in a state in which the overlapping portion is disposed so as to encase the wire;
the overlapping portions of the flexible strip are sandwiched between the wire and the spiral reinforcement on both sides of a portion where the wire is sandwiched substantially along the central axis of the hose, so that the overlapping portions of the flexible strip are in close contact with each other ;
The direction in which the narrowed portion and the hollow portion are aligned is inclined obliquely with respect to the radial direction of the hose.
Flexible hose. 10. A method for producing the flexible hose of claim 1 , comprising the steps of:
a step of helically winding the flexible strip, the helical reinforcement and the wire while bending the metallic strip to form the Ω-shaped cross section and accommodating the overlapped portion of the flexible strip and the wire in the hollow portion being formed,
At the final stage of the above process or subsequent to the above process,
a step of compressing and crimping the hollow portion in a direction in which the wire is sandwiched substantially along a central axis of the hose;
A method for manufacturing a flexible hose.

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