JP7071719B2 - Bent pipe and its manufacturing method, and exhaust pipe system to which this bent pipe is applied - Google Patents

Description

The present invention relates to a bent pipe suitable for being applied to, for example, an exhaust pipe of an internal combustion engine, a method for manufacturing the bent pipe, and an exhaust pipe system to which the bent pipe is applied.

Under the condition of maintaining high quality in all industrial products including automobiles and motorcycles, technical improvements for cost reduction are constantly required. Such a request is the same for, for example, the exhaust system of a motorcycle that uses an internal combustion engine as a prime mover, but the body size of a motorcycle is much smaller than that of an automobile, and as a result, it is extremely difficult. It is required to lay out the exhaust pipe using a narrow space and to withstand the recent sophistication of exhaust gas purification (see, for example, Patent Documents 1 and 2).

Specifically, since the exhaust pipe is a bent pipe and the catalyst unit is housed inside the exhaust pipe in order to effectively utilize the gap around the engine, it is necessary to secure a pipe diameter sufficient to secure this storage space. .. As the exhaust pipe that meets such a requirement, for example, as shown in FIG. 1 (b), a pipe in which an intermediate portion is constricted and the constricted portion is bent can be assumed. In this case, if a plurality of pipe elements having different shapes are prepared and combined in the longitudinal direction of the pipe, a product having the desired shape can be easily obtained, but the manufacturing cost cannot be sufficiently reduced.

By the way, in manufacturing such a pipe body, the metal plate material can be rolled into a tubular shape and bent by sequentially performing so-called U-bending processing and O-bending processing on the metal plate material instead of using the pipe material as a raw material. Although it can be done, in the case of a deformed shape having a bent part and a different diameter part as shown in FIG. There is no pursuit of a solution.

A general method for manufacturing a bent pipe from a metal plate is, as shown in FIG. 5, in a U-bending step so that the seam portion (joining line SL) is on the outer arc side of the bent pipe 1'. Press the inner arc side so that it becomes the U-bent bottom and bend it in a medium-high shape from the side view (see FIG. 5A), and then close the U-shaped cross-section opening by the O-bending process. (See FIG. 5 (b)). As a result, the structure is such that the joint side Wa is seamed on the outer arc side.In this method, almost all parts of the material are subjected to tensile deformation due to plastic deformation, and wrinkles are avoided, but the wall thickness tends to decrease significantly. Therefore, it was hard to say that it was suitable for all target products.

JP-A-2015-190380 (Patent No. 6147219) Japanese Unexamined Patent Publication No. 2017-160792

The present invention has been made in recognition of such various backgrounds, and is based on the premise that the starting material is a flat metal material in order to provide a bent tube product at low cost. The subject was the development of a new bent pipe that can suppress the decrease in the amount of water, a method for manufacturing the bent pipe, and an exhaust pipe system to which the bent pipe is applied.

That is, the bent pipe according to claim 1 is
A metal plate material having an appropriate plate thickness is used as a starting material, and this starting material is rolled into a cylinder to form a tubular body.
Moreover, this pipe body has a bend in the longitudinal direction of the pipe, and a joining line of a joining side is formed on the inner arc side of this bend .
Moreover, the tubular body formed by rolling the starting material into a tubular shape has a constricted portion having a smaller diameter than other portions in the middle portion.
This constricted portion is characterized in that a recessed portion protruding inward from the outside of the tubular body is formed .

Further, the bent pipe according to claim 2 is provided in addition to the requirements according to claim 1.
An engaging protrusion and an engaging receiving portion are formed in advance on the facing joint side of the metal plate material that is rolled into a cylindrical shape. It is characterized by being able to prevent it from coming off.

Further, the method for manufacturing a bent pipe according to claim 3 is as follows.
It is a method of manufacturing a bent pipe by using a metal plate material with an appropriate plate thickness as a starting material for a flat plate starting work and plastically deforming this work.
This metal plate material is rolled into a tubular shape and formed into a desired bent tube through a material preparation step, an outer arc preforming step, a trimming step, a U bending step, and an O bending step in sequence.
In the material preparation process, a flat plate-shaped initial work piece having a required shape is obtained.
Next, in the outer arc preforming step, an outer arc pre-bent portion is formed with respect to the flat plate starting work to obtain an outer arc preforming work.
Next, in the trimming step, a blank work is obtained by removing the margin portion unnecessary for realizing the tubular cross section of the bent pipe from the outer peripheral portion of the outer arc pre-bent portion in the outer arc preform work.
Next, in the U-bending step, the flat plate portion around the outer arc preliminary bending protrusion in the blank work is raised in the pipe radial direction to form a U-shape in cross-sectional view, and the curvature of the outer arc curved surface in the pipe longitudinal direction. Formed in a curved shape with a U-bending work,
Next, in the O-bending step, both ends of the U-bending work in the pipe radial direction are deformed into an inner round shape and brought into contact with each other to obtain an O-bending work having a tubular cross section in which the contact line is located on the inner arc side. It is characterized by the fact that it completes a bent pipe.

Further, the method for manufacturing a bent pipe according to claim 4 is, in addition to the requirements according to claim 3 , in addition to the requirements according to claim 3.
In the blank work, an engaging protrusion and an engaging receiving portion are formed on the facing joint side, and when joining the joining side, the engaging protrusion is fitted into the engaging receiving portion to prevent the joint sides from coming off. It is characterized by the fact that it has been done.

Further, in the method for manufacturing a bent pipe according to claim 5 , in addition to the requirements according to claim 3 or 4 , in the trimming step, the material dimensions in the pipe radial direction of the blank work are set in the middle portion of the bent pipe in the completed state. By making it shorter than other parts, it is characterized by making a constricted part with a smaller diameter than other parts appear.

The exhaust pipe system according to claim 6 is
It is characterized in that the catalyst unit for an internal combustion engine is housed on both sides of the bent portion of the bent pipe according to claim 1 or 2 .

Further, the exhaust pipe system according to claim 7 is provided in addition to the requirements according to claim 6 .
A constricted portion having a small diameter is formed in the middle portion of the curved pipe in which the catalyst unit is not housed.
This constricted portion is characterized in that a concave portion protruding from the outside of the bent pipe to the inside of the pipe is formed in a spiral shape.

The above-mentioned problems can be solved by using the constitution of the invention described in each of these claims as a means.
That is, according to the invention of claim 1, the metal plate is rolled into a cylindrical shape to obtain a bent pipe, and the joining line of the joining side is formed on the inner arc side of the bent pipe, so that it is on the outer arc side. In the present invention, the decrease in wall thickness, which often occurs when a joining line is formed, can be suppressed.
Further, according to the present invention, the bent pipe has a constricted portion having a smaller diameter than other portions in the middle portion, and a concave portion protruding inward from the outside of the tubular body is formed in this constricted portion. During the process of rolling the material into a tubular shape, the recessed portion allows the excess meat that tends to occur in the constricted portion to escape. For this reason, the load applied to the mold and the material during processing can be suppressed, smooth material flow can be promoted, and the constricted portion can be realized in a desired shape (improvement of shape feasibility).

Further, according to the invention of claim 2 or 4 , an engaging protrusion and an engaging receiving portion are formed in advance on the opposing joint side of the metal plate material, and the engaging protrusion is engaged at the time of joining the joint side. Since the joints are fitted into the receiving part to prevent the joints from coming off, the joints can be firmly joined without special welding, and the joint line after joining can be maintained firmly. can.

Further, according to the invention of claim 3 , the bent pipe is desired to be subjected to an outer arc preforming process on the flat plate initial work, a margin portion removed in a trimming step, and then a U bending process and an O bending process. It is processed into a shape. For this reason, in order to obtain a bent pipe by rolling the flat plate starting work into a tubular shape, a concrete method of locating the joining line of the joining side on the inner arc side of the bending in the longitudinal direction of the pipe is realized.

Further, according to the invention of claim 5 , in the trimming step, a constricted portion appears in the middle portion of the bent pipe depending on the material size in the pipe radial direction of the blank work, so that the work (blank work) after removing the blank is U-bent. When the mold or the work is rolled into a tubular shape by processing or O-bending, an extra load is not applied to the mold or the work, and the constricted portion can be smoothly formed.

Further, according to the invention of claim 6 , since the catalyst unit is housed on both ends of the bent pipe, it is possible to provide an exhaust pipe system having excellent purification performance.

Further, according to the invention of claim 7 , in the bent pipe applied to the exhaust pipe system, a concave portion protruding from the outside of the pipe to the inside of the pipe is spirally formed in the constricted portion, so that the exhaust gas is discharged. When passing through here, swirls can be generated efficiently.

It is a perspective view (a) which shows an example of an exhaust muffling unit (exhaust pipe system) which applied the bent pipe of this invention as an exhaust pipe, and is the perspective view (b) which shows the bent pipe part enlarged. It is explanatory drawing which shows the manufacturing method of a bent tube step by step. When the blank work (after trimming) on which the outer arc preliminary bending protrusion is formed is rolled into a tubular shape and formed into a pipe body (bending pipe), the engaging protrusions and engagement acceptance are received at the facing joint sides of the work during trimming. A perspective view (a) of a blank work showing a state in which a portion is formed, a perspective view (b) showing a bent pipe obtained by subjecting the blank work to a U-bending process or an O-bending process, and a U-bending process or the like. It is a front view (c) which skeletonly shows the shape change of the pipe body cross section (work cross section) by O bending process. An explanatory view (a) showing an enlarged view of an engaging protrusion and an engaging receiving portion formed on a pair of joint sides of a blank work in a plan view, and an O-bending process for rounding the work on one of the joint sides. It is explanatory drawing (b)-(f) which shows the mode that the formed engagement protrusion is fitted into the engagement receiving part formed in the other joint side in a stepwise manner. It is a perspective view stepwise showing a conventional manufacturing method of forming a curved pipe by rolling a metal plate material having an appropriate plate thickness into a cylindrical shape, and shows a state in which a joining line is positioned on the outer arc side of the curved pipe. It is a perspective view which shows.

The best mode for carrying out the present invention is one of those described in the following examples, and also includes various methods that can be improved within the technical idea.
In the description, the exhaust muffling unit U (exhaust pipe system) to which the curved pipe 1 of the present invention is applied will be described first, and then the curved pipe 1 of the present invention will be described. Of course, the bent pipe 1 of the present invention can be widely applied not only to the exhaust pipe U1 but also as a bent pipe product for various purposes.

As shown in FIG. 1, the bent pipe 1 of the present invention can be applied as an exhaust pipe U1 forming an outer cylinder of an exhaust muffling unit U constituting an exhaust gas G discharge path such as a muffler or an exhaust pipe. The exhaust muffling unit U purifies the exhaust gas G discharged from the engine after combustion before it is released into the atmosphere.
Further, a catalyst unit 2 is incorporated in a fixed state inside the exhaust pipe U1 (bent pipe 1), and a catalyst medium (catalyzer substance) for reducing harmful substances is adhered and formed on the wall surface of the flow path of the catalyst unit 2 to exhaust. While passing through the inside of the catalyst unit 2, the gas G comes into contact with the catalyst media and is purified.
Including the exhaust muffling unit U, these may be referred to as an exhaust pipe system as a whole.

Further, the catalyst unit 2 includes a honeycomb type catalyst core 21 having a large number of reaction holes along the flow direction of the exhaust gas G, and a holding outer frame 22 fitted on the outer peripheral side thereof. That is, the catalyst unit 2 is formed by providing the catalyst core 21 as a honeycomb inside the holding outer frame 22 as an outer cylinder opened in the front-rear direction.
The honeycomb type catalyst core 21 has a honeycomb-shaped cross section (flow path cross section) in order to secure a contact area with the exhaust gas G as large as possible. Incidentally, in order to form such a honeycomb type catalyst core 21, for example, a corrugated sheet (corrugated sheet having a flow path cross-sectional waveform) is formed by corrugating from a single flat metal material, and this corrugated sheet is formed. It can be formed by winding while overlapping with another flat plate. Here, the flat plate is corrugated in order to form an exhaust gas flow path as a cell.
Further, FIG. 1A shows a form in which the catalyst unit 2 is incorporated in both the muffler and the exhaust pipe (on both sides of the bent portion 10 described later) to purify the exhaust gas G in two stages. However, such a form in which the catalyst unit 2 is incorporated in a multi-stage manner is a structure adopted when it is desired to further improve the purification performance of the exhaust gas G, and depending on the required purification performance, it may be used in a muffler or an exhaust pipe. It is possible to incorporate the catalyst unit 2 in only one place.

Next, the holding outer frame 22 will be described.
As shown in FIG. 1A as an example, the holding outer frame 22 includes a core grip portion 221 circumscribing the catalyst core 21 and an inner fitting portion 222 inscribed in the curved pipe 1 (exhaust pipe U1). The core gripping portion 221 and the inner fitting portion 222 are formed in a stepped cross-sectional view so that the inner fitting portion 222 has a large diameter at each other's diameter. That is, the holding outer frame 22 firmly holds the catalyst core 21 inserted therein by having the core gripping portion 221 and by having the inner fitting portion 222, the holding outer frame 22 ( The holding outer frame 22) in which the catalyst core 21 is internally fitted can be reliably fixed in the exhaust pipe U1, and is formed as an outer cylinder having a step as a whole.

Here, the arrangement of the core grip portion 221 and the inner fitting portion 222 is such that the large diameter inner fitting portions 222 are located on both sides of the small diameter core grip portion 221 as shown in FIG. 1A as an example. When looking at one catalyst unit 2, it is formed in the order of the inner fitting portion 2222-the core gripping portion 221-the inner fitting portion 222. In this case, a gap (space) with the bent pipe 1 (exhaust pipe U1) is formed at the central portion (center portion in the axial direction) of the holding outer frame 22, and the bent pipe 1 is in contact with both ends thereof.

Next, the bent pipe 1 will be described.
As shown in FIG. 1 as an example, the curved pipe 1 is formed so as to draw a curve in the longitudinal direction of the pipe, that is, in the flow direction of the exhaust gas G, and the outer side (outer arc side) portion of the curve. Is referred to as an outer arc curved surface CVo, while the inner (inner arc side) portion of the curve is referred to as an inner arc curved surface CVi.
It should be noted that the bending in the longitudinal direction of the pipe is slightly different from the "bending portion 10" described in the present specification, and this will be described below. For example, when the bent pipe 1 has a "K" -shaped bend , the portion corresponding to the bending point of the "K" character is the "bent portion 10". On the other hand, the curved curve formed as a whole in the longitudinal direction of the pipe is referred to as "curve in the longitudinal direction of the pipe".

Further, in the bent pipe 1, a constricted portion 11 having a smaller diameter (smaller diameter) than other portions is formed in an intermediate portion (here, substantially the central portion) of the tube main body. Therefore, in this embodiment, the portion having the bent portion 10 also has the constricted portion 11 at the same time.
Further, as shown in FIG. 2 (e) or the like, a recessed portion 12 protruding inward from the outside of the tubular body is formed in the constricted portion 11.
The recessed portion 12 is formed in a spiral shape, for example, along the inner surface of the pipe, thereby efficiently generating a swirl. Of course, when the bent pipe 1 is not applied as the exhaust pipe U1, there is no effect of generating such a swirl, but even in such a case, the recessed portion 12 is formed in the constricted portion 11 (bent portion 10). This has the effect of absorbing the excess meat (the excess meat due to processing) at the site.
Incidentally, the recessed portion 12 enlarged and shown in FIG. 2 (e) is shown in a state of looking into the inside of the pipe line from the open end portion of the bent pipe 1 in the completed state.

Further, such a bent pipe 1 is obtained by rolling a metal material having an appropriate plate thickness into a tubular shape by plastic working using a press die, and therefore, in the bent pipe 1. As an example, an engaging protrusion 4 and an engaging receiving portion 5 as shown in FIG. 1 (b) are formed on both end edges (joining side Wa) to be joined, and when the both ends are joined, the engaging protrusion 4 is formed. It is fitted into the engagement receiving portion 5 to prevent the joint sides from coming off.
Here, the reference numeral SL in the figure indicates a joining line in which a pair of joining sides Wa are joined in the bent pipe 1 in the completed state, and this joining line SL can be positioned on the inner arc side of the bent pipe 1. This is a major feature of the bent pipe 1 according to the present invention.

Next, an example of the method for manufacturing the bent pipe 1 as described above will be described.
As shown in FIG. 2, the bent pipe 1 uses a metal material having a substantially constant plate thickness as a starting material (this is referred to as a flat plate starting work W1), and the flat plate starting work W1 is made into a tubular shape. It is formed in a curved tube 1 having a tubular cross section by being plastically formed so as to be rolled.
Specifically, the material preparation step shown in FIG. 2 (a), the outer arc preforming step shown in FIG. 2 (b), the trimming step shown in FIG. 2 (c), the joint pre-bending step, and FIG. 2 (d). The U-bending step shown in FIG. 2 and the O-bending step shown in FIG. 2 (e) are sequentially performed to obtain a bent tube 1 in a completed state. Here, the shape of the metal plate material that is the work W gradually changes by going through the various steps described above. Therefore, if it is desired to distinguish the work W each time the work W is passed, the work W is used for each work. W1, W2, ... Are distinguished by adding a suffix (the name of each work will be described later).
In the trimming step, as shown in FIGS. 3 (a) and 4 (a), the engaging projection 4 and the engaging receiving portion 5 are placed on the opposing joint side Wa in the work W (blank work W3 described later) as an example. Is formed together (formed together with the trimming cut), and in the O-bending step, the engaging protrusion 4 is fitted into the engaging receiving portion 5 to prevent the joint sides from coming off from each other. As a result, a non-welded seam pipe as a pipe material (steel pipe) that does not require welding of the joint side Wa can be obtained.
Hereinafter, each step will be described.

(1) Material preparation step The material preparation step is a step of obtaining a flat plate initial work W1 having a required shape, as shown in FIG. 2A as an example. Here, in FIG. 2A, a rectangular (rectangular) work W in a plan view is shown as the first flat plate work W1. However, in order to remove an unnecessary margin portion M in the trimming step performed later, the first flat plate is fired. The work W1 does not necessarily have to have a rectangular shape.

(2) Outer arc preforming step In the outer arc preforming step, as shown in FIG. 2B as an example, the outer arc pre-bending protrusion 15 is formed on the flat plate initial work W1 and the outer arc preforming is formed. This is a process for obtaining the work W2. Here, the outer arc preliminary bending protrusion 15 has a substantially semi-cylindrical shape that is previously applied to the flat plate starting work W1 in order to realize the outer arc curved surface CVo formed on the curved pipe 1 in the product state with higher accuracy. (Here, the central portion of the curved tube 1 is formed so as to have a semicircular cross section), which is formed as a convex shape protruding toward the outer arc side in the longitudinal direction of the tube. The outer arc preliminary curved protrusion 15 has a concave shape when viewed from the inside of the completed curved pipe 1 (exhaust pipe U1), but this portion is for faithfully reproducing the outer arc curved surface CVo. Because it is a thing, the name is also called "protrusion".
Further, the outer arc pre-molded work W2 on which the outer arc pre-bent protrusion 15 is formed has a shape in which each side around the work is pulled toward the center side (outer arc pre-bent protrusion 15). In particular, here, the pair of joint sides Wa on which the engagement protrusion 4 and the engagement receiving portion 5 are formed are pulled to the center side (outer arc preliminary bending protrusion 15) larger than the other set of sides. It becomes a state.

(3) Trimming step As shown in FIG. 2 (c) as an example, in the trimming step, a tubular cross section of a bent pipe 1 is realized in the outer peripheral portion of the outer arc preliminary bending protrusion 15 in the outer arc preforming work W2. This is a step of removing a portion (this is referred to as a margin portion M) that is unnecessary for the blank work W3. That is, in the removal of the margin portion M, in the outer contour setting of the blank work W3 (inner contour setting of the margin portion M), when the facing joint side Wa of the blank work W3 is rounded into a tubular shape in the blank work W3 after excision. , The shape and dimensions that can realize the desired bent pipe 1 are set.
In the blank work W3, the portion forming the joint side Wa (the portion protruding in a wing shape on both the left and right sides of the outer arc preliminary bending protrusion 15) exhibits a flat plate shape, and this is referred to as a flat plate portion 16. In the subsequent bending process, the flat plate portion 16 is gradually rolled so as to form a tubular cross section.

Further, in this trimming step, in the central portion of the bent pipe 1 in the completed state, the material dimension in the pipe radial direction of the blank work W3 is set to be shorter than that of other parts, and the constricted part having a smaller diameter than other parts in the portion. I am trying to make 11 appear.
Incidentally, such trimming (punching) is performed by general press working, but if the trimming shape, that is, the plan view shape of the blank work W3 is complicated, cutting may be performed by laser processing or the like. ..

Further, in the trimming step, as shown in FIG. 3A as an example, the engaging projection 4 and the engaging receiving portion 5 are formed on the opposing joint side Wa in the blank work W3 (FIG. 2). (C) is not shown), the details of which will be described later. Incidentally, in this embodiment, five engaging protrusions 4 are formed on one side constituting the joint side Wa as an example, and an engaging receiving portion 5 is formed on the other joint side Wa facing the same as an example. It was formed in one place (see FIGS. 1 (b) and 3 (b)).

Then, with respect to the blank work W3 thus obtained, for example, as shown in FIG. 3 (c), the joint pre-bending process (processing of (1) in the figure) and U-bending process ((1) in the figure). The bent pipe 1 as shown in FIG. 3 (b) is obtained by performing the processing of 2) and the O-bending processing (processing of (3) in the figure). Hereinafter, the shapes (examples) of the engaging protrusions 4 and the engaging receiving portions 5 formed on the pair of joining change Wa in the blank work W3 and each bending process will be described in detail.

In order to obtain the above-mentioned non-welded seam pipe (bent pipe 1), for example, as shown in FIGS. The protrusion 4 and the engagement receiving portion 5 having a corresponding shape are formed. Here, the engaging protrusion 4 has a shape including, for example, a bifurcated projecting piece 41 protruding from the joint side Wa and divided into a bulging shape. Then, by providing the retaining constriction portion 43 on the joining side Wa side of the bifurcated projecting piece 41, that is, near the engaging base portion 42, the projecting piece 41 eventually forms a forked shape. Is formed in. Further, the projecting pieces 41 are formed in a bifurcated shape, and as a result, a notch-shaped deformation allowable portion 44 is formed between the pair of projecting pieces 41. Further, the engaging projection 4 is provided with a smooth arc-shaped engaging guiding surface 46 on the outer tip of the widest projection wide portion 45 in order to exert various actions during manufacturing. The tip portion thereof is referred to as an engaging tip portion 47. The surface of the engaging projection 4 at the portion of the deformation allowable portion 44 is designated as the deformation return surface 48.

On the other hand, the engagement receiving portion 5 is formed in a notch shape having a shape similar to that of the engaging protrusion 4 in a plan view, and is similarly notched in a bifurcated shape from the joint side Wa toward the back. It has a notch 51.
Then, the acceptance start portion 52 near the joint side Wa is formed in an inclined shape so as to be slightly narrowed from the joint side Wa toward the inner portion, and further, the inner portion side of the acceptance start portion 52 is formed in a constricted shape. Is used as a retaining and closing portion 53. On the other hand, a deformation return portion 54 is provided from the center of the innermost portion of the engagement receiving portion 5 toward the joint side Wa side. The engagement receiving portion 5 forms a receiving securing surface 56 closest to the innermost portion thereof, and the innermost portion of the engaging receiving portion 5 is further referred to as a receiving inner portion 57. Further, the outer peripheral surface of the protrusion-shaped deformation return portion 54 is designated as the deformation return surface 58. Then, in the completed form of the pipe as the bent pipe 1, the engaging projection 4 having substantially the same shape in a plan view and the engaging receiving portion 5 are combined in a meshed state to present a completed state. The structure combined with such a meshed state is called "hammer-headed tenon" in the construction industry.

The engaging projection 4 and the engaging receiving portion 5 can have the above-mentioned shapes, and a method for manufacturing a bent pipe 1 (non-welded seam pipe) based on these shapes will be described below.
In manufacturing the bent pipe 1, as described above, the blank work W3 that has completed the trimming step is sequentially subjected to joint pre-bending, U-bending, and O-bending, and the engaging protrusion 4 and The joining with the engagement receiving portion 5 is also performed in the O bending process.
Hereinafter, each bending process will be described.

(4) Joint pre-bending step The joint pre-bending step is mainly applied to the joint Wa portion in order to firmly join the joint Wa as shown in (1) of FIG. 3 (c) as an example. It is a preliminary bending process, and more specifically, it is considered that when the work W is finally O-bending process, the joint portion tends not to have a pipe-shaped tubular cross section due to the influence of springback or the like. Then, only the portion near the joint side Wa is preliminarily rounded so that the completed pipe (bent pipe 1) draws an arc cross section.
Then, these can be surely and firmly joined without welding or the like to the joint side Wa by the processing. Here, the work W that has completed the joint pre-bending step is referred to as a joint pre-bending work W4.

In the bending steps such as the joint pre-bending step, the U-bending step, and the O-bending step, the press processing is performed by an upper die or a lower die that matches the molding shape, and the die itself is designed to reproduce the shape. Since it is formed into a unique shape, the description of the mold will be omitted. Of course, this also applies to the outer arc preforming step and the trimming step.
By the way, in the above explanation, the mold is referred to as the upper mold and the lower mold, but this follows (uses) the commonly used name, and the actual mold arrangement is diagonal arrangement or horizontal arrangement. It doesn't matter what you do.

(5) U-bending step In the U-bending step, as shown in (2) of FIGS. 2 (d) and 3 (c), the left and right of the outer arc preliminary bending protrusion 15 in the joint preliminary bending work W4 This is a step of raising the flat plate portion 16 formed in the above direction in the radial direction of the pipe to form a U-shape in cross-sectional view. That is, the joint pre-bending work W4 has a form in which the flat plate portions 16 projecting substantially horizontally are provided on both ends of the outer arc pre-bending protrusion 15 protruding toward the outer arc side. 2 (d) -The U-bending process is to form a U-shaped cross section as shown in (2) of FIG. 3 (c).
Further, in this U-bending step, the joint pre-bending work W4 is formed into a curved shape having a curvature of the outer arc curved surface CVo when viewed in the longitudinal direction of the pipe, and has a U-shaped cross section by the processing. In addition, it forms a work W having a bend in the longitudinal direction of the pipe, and this is a U-bending work W5.
In this embodiment, the recessed portion 12 of the constricted portion 11 is also processed in the U bending step.

(6) O-bending step In the O-bending step, as shown in FIG. 2 (e) and FIG. This is a step of deforming the pipes into an inner round shape and bringing them into contact with each other, whereby the joint line SL of the joint side Wa is located on the inner arc side of the curved pipe 1. Then, by the process, the work W becomes an O-bending work W6 having a tubular cross section, which is a bent pipe 1 as a finished product.

In the embodiment shown in FIG. 2, the concave portion 12 of the constricted portion 11 is shown so as to be completed in a desired shape between the U bending step and the O bending step, but the unevenness of the concave portion 12 and the like are shown. Depending on the case, it is also possible to gradually form the recessed portion 12 from an earlier stage, for example, the outer arc preforming step, and complete it in the O-bending step.

Further, in the above description, a form in which the blank work W3 after the trimming step is subjected to the joint pre-bending process and then the joint pre-bending work W4 is subjected to the U-bending process is basically described. The partial pre-bending step may be omitted depending on the shapes of the engaging projection 4 and the engaging receiving portion 5, and therefore, in FIG. 2, the joint pre-bending step is omitted.

(7) Engagement action Then, in the O-bending step, as described above, an engagement action is exerted on the engagement projection 4 and the engagement receiving portion 5 which are close to each other, and the joint sides Wa are firmly engaged with each other. This is the case, and this engagement mode will be described below.
(7-a) At the start of engagement When the O-bending process progresses, as shown in FIG. 4 (b) as an example, first, the engagement protrusions 4 and the engagement receiving portions provided opposite to each other on the joint side Wa Contact with 5. At the start of this contact, the arc-shaped engaging guide surface 46 in the range slightly outward from the engaging tip portion 47 of each of the projecting pieces 41 divided into two branches in the engaging projection 4 is the engaging receiving portion. Contact the acceptance start unit 52 in 5.
Further, the deformation allowable portion 44 is further formed in a notch shape by the inclination guidance between the arc-shaped engagement guide surface 46 in the engagement projection 4 and the acceptance start portion 52 inclined in an inwardly constricted shape. Therefore, as shown in FIG. 4 (c), the projecting pieces 41 are deformed so as to approach each other.

(7-b) At the time of engagement induction After continuing the form in which the engagement projection 4 relatively enters the engagement receiving portion 5 in such a state, as shown in FIG. 4 (d) as an example. In addition, the pair of projecting pieces 41 momentarily bend and approach each other, and are deformed as if they slip through the space between the retaining and closing portions 53 formed in a constricted shape to enter the receiving notch 51.
At this time, the pair of projecting pieces 41 that are bent so as to momentarily approach each other has the receiving notch 51 having a bifurcated inward extension shape, so that the pair of projecting pieces 41 will be restored to their original shape by springback accordingly. Continue to enter.
When further entering in this state, as shown in FIG. 4 (e), the deformation allowable portion 44, which is narrow due to the pair of projecting pieces 41 approaching each other, becomes the deformation return portion 54 in the engagement receiving portion 5. Contact with. Then, this movement is further advanced to reach the state at the time of the next engagement completion.

(7-c) At the time of engagement completion As shown in FIG. 4 (f), the state at the time of engagement completion is a state in which the protrusion 41 enters the receiving notch 51 in response to the movement during the engagement induction. When the approach is finally completed, the protrusion-shaped deformation return portion 54 is in a state of being tightly engaged with the deformation allowable portion 44 in the engagement protrusion 4. As a result, the projecting piece 41 is expanded to the original state, and the engagement between the engaging projection 4 and the engaging receiving portion 5 is completed.
In this engagement completed state, the retaining closing portion 43 of the engaging projection 4 is pressed by the retaining closing portion 53 of the engaging receiving portion 5, so that a so-called hammer-headed tenon structure is formed, and the retaining portion is surely shown. Be done.

The details of the method for forming a non-welded seam pipe by rolling a metal plate material as described above are based on the application and follow-up of Japanese Patent Application No. 2016-75416, which the applicant has already filed for a patent application.
Further, in the portion of the joint side Wa where the engagement protrusion 4 and the engagement receiving portion 5 do not exist, a part of the metal material is crushed to form an overlapping portion, which is polymerized to strengthen the joint of the joint side Wa. It is possible to plan, and the "overlapping seam portion" described in the above-mentioned Japanese Patent Application No. 2016-75416 is used and followed for such an overlapping portion.

By the above method, a pipe material can be obtained while using a metal plate material as a starting material, and the joint side Wa is firmly joined to each other only by a butt action without welding. A welded seam pipe (bent pipe 1) can be obtained.
When welding the joint side Wa, the reliability of the welding quality is often an essential problem of the pipe material as a finished product. In other words, even if welding seems to be done well at first glance, it may be unclear whether the inside is surely welded, and it is necessary to suppress the defect rate of the finished product (welded product). High technology was required, and the cost tended to increase accordingly.
For this reason, in the past, when rolling a metal plate to obtain a pipe material, it was required to weld the edge portion, especially with high precision, but with the above method, welding is particularly necessary. It is extremely excellent in that the joint side Wa, which is a seam, can be joined at the same time as the O-bending process when the metal plate material is rolled into an O-shape.

Further, since the joint side Wa of the work W can be joined without welding, it is possible to reduce the welding process and thus simplify the manufacturing process of the pipe material. Of course, it is possible to completely eliminate welding defects (joining defects) that have conventionally occurred during welding.
Furthermore, if you just want to obtain a pipe material, you can purchase a commercially available one, or you can purchase a long pipe material and cut it to a desired length. In such cases, off-the-shelf products that are already formed in the shape of a pipe are often expensive (especially overseas), so the above method (and end edge joining) that allows a non-welded seam pipe to be obtained from a metal plate material. (No welding is required) is also very effective in that the pipe material can be obtained at an extremely low cost.

U Exhaust silencer unit U1 Exhaust pipe 1 Bent pipe 2 Catalyst unit 21 Catalyst core 22 Holding outer frame 4 Engagement protrusion 5 Engagement receiving part

1 Bent pipe 10 Bent part 11 Constricted part 12 Recessed part 15 Outer arc preliminary bent part 16 Flat plate part CVo Outer arc curved surface CVi Inner arc curved surface M Margin part

22 Holding outer frame 221 Core grip (small diameter)
222 Inner fitting part (large diameter)

4 Engagement protrusion 41 Projection piece 42 Engagement base 43 Retaining constriction part 44 Deformation allowable part 45 Protrusion wide part 46 Engagement guide surface 47 Engagement tip part 48 Deformation return surface

5 Engagement receiving part 51 Accepting notch 52 Accepting start part 53 Retaining blocking part 54 Deformation return part 56 Acceptance securing surface 57 Acceptance back part 58 Deformation return surface

G exhaust gas

W work Wa joint side W1 flat plate starting work W2 outer arc preforming work W3 blank work W4 joint pre-bending work W5 U bending work W6 O bending work SL joint line

Claims (7)

A metal plate material having an appropriate plate thickness is used as a starting material, and this starting material is rolled into a cylinder to form a tubular body.
Moreover, this pipe body has a bend in the longitudinal direction of the pipe, and a joining line of a joining side is formed on the inner arc side of this bend .
Moreover, the tubular body formed by rolling the starting material into a tubular shape has a constricted portion having a smaller diameter than other portions in the middle portion.
A bent pipe characterized in that a recessed portion protruding inward from the outside of the tubular body is formed in this constricted portion .
An engaging protrusion and an engaging receiving portion are formed in advance on the facing joint side of the metal plate material that is rolled into a cylindrical shape. The bent tube according to claim 1, wherein the bending tube is prevented from coming off.
It is a method of manufacturing a bent pipe by using a metal plate material with an appropriate plate thickness as a starting material for a flat plate starting work and plastically deforming this work.
This metal plate material is rolled into a tubular shape and formed into a desired bent tube through a material preparation step, an outer arc preforming step, a trimming step, a U bending step, and an O bending step in sequence.
In the material preparation process, a flat plate-shaped initial work piece having a required shape is obtained.
Next, in the outer arc preforming step, an outer arc pre-bent portion is formed with respect to the flat plate starting work to obtain an outer arc preforming work.
Next, in the trimming step, a blank work is obtained by removing the margin portion unnecessary for realizing the tubular cross section of the bent pipe from the outer peripheral portion of the outer arc pre-bent portion in the outer arc preform work.
Next, in the U-bending step, the flat plate portion around the outer arc preliminary bending protrusion in the blank work is raised in the pipe radial direction to form a U-shape in cross-sectional view, and the curvature of the outer arc curved surface in the pipe longitudinal direction. Formed in a curved shape with a U-bending work,
Next, in the O-bending step, both ends of the U-bending work in the pipe radial direction are deformed into an inner round shape and brought into contact with each other to obtain an O-bending work having a tubular cross section in which the contact line is located on the inner arc side. , A method for manufacturing a bent pipe, which is characterized in that it completes a bent pipe.
In the blank work, an engaging protrusion and an engaging receiving portion are formed on the facing joint side, and when joining the joining side, the engaging protrusion is fitted into the engaging receiving portion to prevent the joint sides from coming off. The method for manufacturing a bent pipe according to claim 3 , wherein the bending pipe is made in this manner.
In the trimming step, in the middle part of the bent pipe in the completed state, the material size in the pipe radial direction of the blank work is made shorter than the other parts so that a constricted part having a smaller diameter than the other parts appears. The method for manufacturing a bent pipe according to claim 3 or 4 , wherein the bent pipe is manufactured.
An exhaust pipe system to which a bent pipe is applied, wherein the catalyst unit for an internal combustion engine is housed on both sides of the bent portion of the bent pipe according to claim 1 or 2 .
A constricted portion having a small diameter is formed in the middle portion of the curved pipe in which the catalyst unit is not housed.
The exhaust pipe system to which a bent pipe is applied according to claim 6 , wherein a recessed portion protruding from the outside of the bent pipe to the inside of the pipe is formed in a spiral shape in the constricted portion.

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