JP2018035713A - Coupling and method for manufacturing coupling elements constituting the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a new coupling enabling close contacting force (axial force) between housings to be kept rigidly even if it is used for a long period of time and a method for manufacturing the same for the coupling for fastening housings of a turbocharger used at an engine for a vehicle and the like, for example.SOLUTION: A coupling 1 of this invention comprises a pair of semi-circular arc-shaped coupling elements 2 and is constituted in such a way that one-ends of the coupling elements 2 are fixed by a connection member 3 and the other ends can be opened or closed and further the opening or closing ends of the coupling elements 2 are formed with flanges 4 protruded outward, a fastening tool 7 such as a bolt and a nut is arranged at the flanges 4, the flanges 4 are provided with abutment parts 5 more outside than the fastening tool 7. When the coupling 1 is fastened, it shows a feature that the flanges 4 are kept in a separated state and at first the abutment parts 5 are abutted.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a coupling for fastening housings in a turbocharger used in, for example, an automobile engine, and the like, and particularly, the adhesion force (axial force) between fastened housings is strengthened even when used for a long period of time. The present invention relates to a novel coupling that can be maintained and a manufacturing method thereof.

A turbocharger is known as a turbocharger used as a means for increasing the output and performance of an automobile engine. The turbocharger drives a turbine rotor by the exhaust energy of the engine, and a compressor is output by the output of the turbine rotor. Is a device that brings the engine to a supercharged state that is higher than that of natural intake.
As an example, as shown in FIG. 6A, the turbocharger TC is provided with a turbine housing H2 and a compressor housing H3 so as to sandwich a bearing housing (center housing) H1 that rotatably supports the turbine rotor R. . Here, the turbine housing H2 is a casing member that covers the periphery of a turbine wheel TW (an impeller that rotates by the force of exhaust gas) provided at one end of the turbine rotor R, and the compressor housing H3 is another member of the turbine rotor R. It is a casing member which covers the circumference | surroundings of the compressor wheel (compressor impeller) CW provided in one end (other end).

The bearing housing H1 and the turbine housing H2 are usually fastened by a coupling 1 ′, which is often referred to as “G coupling”, “V band coupling” or the like.
The bearing housing H1 and the turbine housing H2 fastened by such a coupling 1 ′ are formed with flange portions FL1 and FL2 protruding in advance on the outer peripheral side, and the coupling 1 ′ has both flange portions. A fastening method is adopted in which the two are fastened together with FL1 and FL2 in contact with each other (see, for example, Patent Documents 1 to 3).

As an example, this type of coupling 1 'includes a pair of half-divided members having a semicircular arc shape as main members (this is called a coupling element 2') as shown in FIG. The other end side can be freely opened and closed (opened / closed) by fastening one end of the object with a ring-shaped connecting member 3 ′ or the like.
The opening / closing end (opening / closing free end side) is formed with a flange portion 4 ′ protruding outward (outer peripheral side when the coupling portion sandwiching both housings is viewed as the inside), and this pair of flange portions 4 'is inserted with a fastening tool 7' such as a bolt or nut, and the fastening tool 7 '(bolt or nut) is tightened with a specified torque T to thereby provide an inner coupling working diameter (each housing H1, This is a portion that is fastened with H2 interposed therebetween, and may be simply referred to as a working diameter hereinafter) to be narrowed to an appropriate diameter, and the two housings H1 and H2 are fastened with a specified adhesion force (axial force). . Note that the two housings H1 and H2 fastened with a predetermined adhesion force are set so that the two flange portions 4 'facing each other at the opening and closing end portions are in a substantially parallel state maintaining an appropriate gap. It is common.

  In addition, as shown in the sectional view of FIG. 7A, the semicircular arc-shaped portion of the half-shaped coupling element 2 ′ has a sandwiching surface 20 ′ for sandwiching the two housings H1 and H2 in a V-shaped section or The two housings H1 are formed by tightening the fastener 7 'while sandwiching the flanges FL1 and FL2 of the two housings H1 and H2 between the inclined surfaces. , H2 is more firmly attached (see FIG. 6A). That is, by tightening the fastener 7 ', the two housings H1 and H2 with which the flange portions FL1 and FL2 abut are moved in the pressing direction along the inclined surface (clamping surface 20') of the coupling 1 '. In addition, the structure is further in close contact. The close contact force acting on the two housings H1, H2 by tightening the tightening tool 7 'acts along the inclined surface (clamping surface 20') of the coupling element 2 '. The more you tighten, the stronger it becomes.

However, such a coupling 1 'has the following problems.
That is, as shown in FIG. 7B, for example, as shown in FIG. 7B, the coupling 1 ′ has a working diameter portion on the inner side of the coupling even if the fastener (bolt / nut) 7 ′ is tightened with a predetermined torque T. Due to the presence of the sandwiched housings H1 and H2, the force F acts on the flange portion 4 'outside the coupling, and the flange portion 4' may be deformed. . This is an inclined deformation that causes the opening / closing end side of the flange portion 4 'to be narrowed, and is a phenomenon in which the rigidity of the coupling 1', particularly the rigidity of the flange portion 4 'is low, that is, the flange portion 4' is lost.
In this case, even if the flanges 4 ′ approach each other and the gap between both narrows (in fact, it is inclined but difficult for the operator to judge), the inner working diameter portion has a specified diameter. The dimension does not reach (is not narrowed), and the housings H1 and H2 are not fastened with a specified adhesion force.
Then, if it is used in such a situation, the housings H1 and H2 fastened during use loosen and leak exhaust gas from here, and not only the original performance can be obtained, but also the turbocharger TC Damage to itself was also assumed.

In FIG. 7 (c), torque T 'is further applied to the fastener (bolt / nut) 7' to narrow the inner working diameter portion from the state of FIG. 7 (b) to the original working diameter. This is a skeletal view of the state of tightening. In this case, a force F ′ further acts on the flange portion 4 ′, and not only the flange portion 4 ′ is further deformed (inclination deformation that further narrows the open / close end side), but the deformed flange portion 4 ′. As a result, the bolt head and nut are tilted like a lever, and as a result, the entire fastener 7 'is bent. Naturally, even in such a situation, the inner working diameter portion is not narrowed to a specified diameter, and therefore the housings H1 and H2 are not fastened with a specified torque.
As described above, in the conventional coupling 1 ′, even if the fastener (bolt / nut) 7 ′ is tightened with the specified torque T (or a torque T ′ higher than the specified value), the working diameter portion inside the coupling is not specified. In some cases, the diameter could not be reduced, which was a problem.

Of course, if the material of the coupling 1 'is made of a high hardness material or the plate thickness of the coupling 1' is increased, the rigidity of the coupling 1 'is improved, and this problem (when a prescribed torque is applied) It is relatively easy to understand that the phenomenon that the flange portion 4 'is deformed) can be avoided. However, increasing the hardness of the material, increasing the thickness of the plate, and the like have led to an increase in material cost. Furthermore, in such a measure, for example, when the clamping surface 20 'of the coupling 1' or the half-like coupling element 2 'is formed by pressing, it is necessary to greatly improve the processing capability of the press machine. For example, the conventional manufacturing method is greatly changed, which causes an extremely excessive cost increase. For this reason, measures such as increasing the hardness of the material and increasing the plate thickness are not easy measures that can be easily introduced at actual sites, although they are easy to understand.
In particular, in recent years, miniaturization of automobile engines has been demanded. Along with this, turbochargers are also required to be lighter and lower in cost, and further improvements in basic performance are being pursued, and the load on turbochargers is increasing. It's getting tougher (especially so-called sports cars). In addition, automobile manufacturers have to cope with fuel efficiency improvements and environmental regulations, and the load on the turbocharger is becoming more severe.

JP-A-7-233888 JP 2006-258108 A JP 2009-167971 A

  The present invention has been made in view of such a background, and when the coupling is tightened with a specified torque without changing the material and thickness of the conventional coupling, the outside of the coupling is obtained. This is an attempt to develop a novel coupling and its manufacturing method in which the working diameter portion on the inner side of the coupling can be narrowed to a specified diameter without losing the flange portion.

That is, the coupling according to claim 1 is:
In a state where the flanges formed at the ends of the fastened bodies are in contact with each other, by sandwiching the flanges, the coupling is configured to fasten the two fastened bodies,
This coupling includes a pair of coupling elements having a semicircular arc shape, and is configured such that one end of each coupling element is fastened with a connecting member so that the other end can be opened and closed. On the open / close end side, a flange portion protruding outward is formed, and a fastener such as a bolt or nut is provided on this flange portion,
Also, the flange portion is provided with an abutting portion on the outer side of the fastener, and when the coupling is tightened, the flange portion is in a separated state, and the abutting portion is first brought into contact with the flange portion. It is.

Further, the coupling according to claim 2 is in addition to the requirement according to claim 1,
The abutting portion is provided so as to be positioned at least at the outer end of the flange portion.

The coupling according to claim 3 is in addition to the requirement according to claim 1 or 2,
In the coupling element, the clamping surface for clamping the flange portion of the body to be fastened is formed in an inclined shape having a V-shaped cross section or a mountain shape in cross section, and the fastened bodies are more firmly attached to each other as the fastener is tightened. Is configured to let
The width dimension of the abutting portion is formed within the width dimension of the clamping surface in a planar development state.

Further, the coupling according to claim 4 is in addition to the requirement according to any one of claims 1 to 3,
The abutting portion is configured by abutting surfaces formed by folding back from a flange portion.

Further, the coupling according to claim 5 is in addition to the requirement according to any one of claims 1 to 4,
A bearing housing that rotatably supports a turbine rotor in a turbocharger used in an automobile engine and a turbine housing that covers the periphery of a turbine wheel provided at one end of the turbine rotor are applied as the fastened body. It consists of features.

Further, the coupling according to claim 6 is in addition to the requirement according to claim 4 or 5,
The pair of butting portions are set in a letter “C” shape that narrows toward the outer tip in an initial state.

Moreover, the manufacturing method of the coupling element of Claim 7 is as follows.
A pair of semicircles constituting a coupling that fastens two fastened bodies by sandwiching the fastened parts in a state where the fastened parts formed at the ends of the fastened bodies are in contact with each other. In producing an arcuate coupling element,
One end of the coupling element is fastened with a connecting member, and the other end side is configured to be openable and closable.
In addition, the flange portion is provided with an abutting portion on the outer side,
In manufacturing the coupling element, it is performed by progressive processing to process the original shape material of the coupling element into a desired three-dimensional shape while being sequentially fed while being connected to a part of the metal plate material,
The manufacturing process is
A blank forming material that is punched to have a volume capable of realizing a desired coupling element from a metal material having a constant plate thickness, and a preform forming step,
The shape material is sandwiched between a pair of opposed molds, at least the shape material is formed in a semicircular arc shape, and the sandwiching surface for sandwiching the flanges of the fastened bodies is formed in a V-shaped cross section or a slope shape having a mountain shape. Modeling process to do,
Comprising a separate step of separating the shaped material after the shaping step from the metal plate,
In addition, in the step of preparing the base material, the abutting portion formed on the outer side of the flange portion is punched out within the width dimension of the clamping surface in a flattened state.

The above-described problems can be solved by using the configuration of the invention described in each of the claims.
In other words, according to the first aspect of the present invention, the working diameter of the coupling is reduced by tightening the fastening tool after the abutting portion provided on the flange portion is brought into contact with the coupling. The working diameter can be reduced. In addition, the conventional coupling has no abutting portion on the flange portion, and the flange portions are set in a separated state in a state where the specified tightening is performed. Even if it is carried out, only the tip (outer side) of the flange portion approaches, and the working diameter of the coupling may not be reduced.

  According to the second aspect of the present invention, since at least the abutting portion is provided at the outer end of the flange portion, the working diameter of the coupling is more reliably reduced after abutting the abutting portion. be able to.

  Further, according to the invention of claim 3 or 7, since the width dimension of the abutting portion is formed within the width dimension of the clamping surface in the flat developed state, when the coupling element is formed by progressive processing, About the blank removal of an element, shape processing, etc., the same method as the past (coupling element which does not have a butting part) can be followed. In other words, in blank removal, when blank material is punched out, the blank material can be extended in the longitudinal direction of the blank material (coupling element) to remove the blank. There is no need to change the direction (the width direction of the blank material). Therefore, conventional progressive processing (press processing) can be substantially followed, and a coupling element can be manufactured without significant process changes.

  According to the invention described in claim 4, since the abutting portion is configured by abutting the surfaces formed by folding back from the flange portion, for example, the abutting portion is brought into a specified tightening state. Can be surely set (abutment setting) in such a manner that they are brought into contact with each other on the same plane. In addition, when the abutting part is simply bent at the tip of the flange part and is abutted with the plate thickness, if there is a burr or the like in the abutting plate thickness part, the above accurate It is difficult to realize the butting setting. In other words, even if there are some burrs on the end face (plate thickness portion) of the abutting portion, if the abutting portion is configured by abutting the surfaces, accurate abutting setting can be realized. .

  Further, according to the invention described in claim 5, since the bearing housing and the turbine housing of the turbocharger for automobiles are applied as the fastened bodies, and these are fastened by the coupling of the present invention, the two housings have strong adhesion. (Axial force) can continue fastening. In addition, the turbocharger for automobiles is repeatedly exposed to a severe environment of high temperature and exhaust gas, and also has a wide range of operating temperatures. In general, the bearing housing and the turbine housing are often formed of different materials, and therefore, the two housings have different expansion rates when subjected to heat, so that they are fastened with strong adhesion (axial force). It was difficult to continue. However, in the present invention, the bearing housing and the turbine housing can be firmly fastened over a long period of time, and even in the harsh environment as described above, both the housings fastened during use can be loosened. It is possible to prevent a situation in which exhaust gas is leaked.

  According to the sixth aspect of the present invention, the abutting portion is placed outside in the initial state (the coupling is mounted so as to surround the outer periphery of the body to be fastened but not yet tightened by the fastening tool). Since it is set in the shape of `` C '' that narrows toward the tip, only the outer tip of the abutting part is brought into contact at the start of abutment, and when the specified tightening state is reached from this state, The abutting portions can be brought into contact with each other, and a stable tightening state can be obtained. In other words, when the abutting portion is set to be almost parallel in the initial state, the tip (outside) of the abutting portion opens in the specified tightening state, and it is difficult to obtain a stable tightening state. .

Sectional drawing (a) which shows a mode that the housing of the turbocharger for motor vehicles was fastened by the coupling of this invention, the side view (b) of this coupling, the perspective view (c) of this coupling, and the abutting part It is the perspective view (d) which partially shows the modification example of this, and the perspective view (e) which partially shows the further modification example of a butting part. The side view (a) which shows an example of the coupling of this invention in an initial state, and the side view which shows the state (state at the time of abutment start) which the abutting part started contact | abutting with tightening of a fastener It is a side view (c) which shows the state (prescribed tightening state) which b) and the fastener was tightened with the regular torque. Side view (a) showing a modified example of coupling with different setting (initial situation) of the abutting part in the initial state, side view (b) showing the coupling in the state at the start of abutting, and regulation It is a side view (c) shown in the tightening state. It is a top view which shows the strip material in the case of forming a coupling element by progressive processing. Explanatory drawing (a) which shows a mode that the outer side front-end | tip part (throttle part) of the flange part in a coupling element was formed in R shape seeing from a plane, and the state which formed the said throttle part in flat shape seeing from the plane It is a top view (b) which shows. Sectional view (a) skeletally showing a state in which a bearing housing (center housing) and a turbine housing of an automobile turbocharger are fastened by a coupling (conventional coupling having no abutting portion), and a coupling of the coupling It is a side view (b). A side view (a) showing a conventional coupling having no abutting portion in an initial state, and a side view (b) showing a state (prescribed tightening state) when the coupling is tightened by a fastener. And a side view (c) showing a state when further tightening is performed.

  The mode for carrying out the present invention includes one described in the following embodiments, and further includes various methods that can be improved within the technical idea.

As described in the background art, the coupling 1 of the present invention has two hooked parts by holding the hooks in a state where the hooks formed at the ends of the fastened bodies are in contact with each other. As shown in FIG. 1 and FIG. 2 as an example, a pair of coupling elements 2 (half members) having a semicircular arc shape are used as main members. One end of the coupling element 2 is fastened by a ring-shaped connecting member 3, and the other end side can be freely opened and closed. Here, the side fastened by the coupling member 3 in the coupling 1 is defined as an opening / closing fulcrum side, and the other end side is defined as an opening / closing end side (opening / closing free end side).
Further, on the open / close end side of the coupling element 2, a flange portion 4 protruding outward (outer peripheral side) is formed. Here, the “outside (of the coupling element 2)” means the outer peripheral side (opening / closing end) when the coupling portion sandwiching the body to be fastened H (the bearing housing H1 and the turbine housing H2 in FIG. 1A) is inside. Side). Further, the flange portion 4 is provided with a fastener 7 such as a bolt or a nut.
Furthermore, the flange portion 4 is provided with an abutting portion 5 at a position outside the fastener 7, and when the coupling 1 is tightened, the flange portion 4 is first left in a separated state, and the abutting portion 5 is firstly opened. Is configured to abut.

Hereinafter, each component of the coupling 1 will be described in detail.
First, the halved coupling element 2 will be described. As shown in the cross-sectional view of FIG. 2A as an example, the coupling element 2 is formed so that the clamping surface 20 that sandwiches the two fastened bodies H has an inclined surface having a V-shaped cross section or a mountain-shaped cross section. In addition, the two fastened bodies H are more firmly adhered to each other by tightening the fastening tool 7 while sandwiching the flanges FL1 and FL2 of the fastened body H between the inclined surfaces. . That is, by tightening the fastener 7, the two fastened bodies H sandwiched between the coupling elements 2 come to press each other along the inclined surface (the sandwiching surface 20) of the coupling 1. The contact force (axial force) of the fastened body H is strengthened.
In addition, such a clamping surface 20 is formed over the entire region of the semicircular arc portion of the coupling element 2 so that the outer peripheral edge of the fastened body H is in close contact with each other.

Next, the flange part 4 is demonstrated.
The flange portion 4 is a portion that is fastened by a fastening tool 7 such as a bolt or a nut, and is formed integrally with the coupling element 2 and extended to the open / close end side (outside).
In addition, as shown in FIG. 1C, for example, the flange portion 4 is provided with an insertion hole 41 for allowing the fastener 7 to pass therethrough, and a portion where the insertion hole 41 is formed has a flat surface shape. It is formed and is configured to be able to hold the fastener 7 stably.
In addition, the insertion hole 41 shown in FIG.1 (c) is opened in planar view rectangular shape, and this is for preventing the idling of the fastener (bolt) 7 in tightening. For this reason, the shaft portion (the shaft portion close to the bolt head) of the fastener 7 that fits into the insertion hole 41 is also formed in a rectangular shape.

Next, the abutting portion 5 will be described.
The abutting portion 5 is provided on the outer side of the fastener 7 and is a portion that is first brought into contact when the coupling 1 is tightened. At this time, the flange portion 4 remains in a separated state. As shown in FIG. 1C and FIG. 2A as an example, the abutting portion 5 is formed so as to protrude further from the front end portion of the flange portion 4 to the outside (front) thereof. Then, it is formed so as to be folded back in two stages so as to draw a crank from the tip of the flange portion 4. For this reason, in the initial state of the coupling 1 shown in FIG. 2A, the separation distance between the pair of abutting portions 5 is shorter than the separation distance between the pair of flange portions 4. The “initial state (of the coupling 1)” described in this specification refers to, for example, tightening while setting the coupling 1 so as to surround the outer periphery of the flanges FL1 and FL2 of the body H to be fastened. This means a free state in which tightening with the tool 7 has not yet been performed.

Next, the fastener 7 will be described.
The fastening tool 7 is a member for fastening the flange portion 4 of the coupling 1 in order to reduce the working diameter inside the coupling, that is, the working diameter of the fastening portion. Here, a combination of bolts and nuts is illustrated. However, it is possible to apply swing bolts, patchon locks (fasteners), and the like.

The coupling 1 of the present invention is one of the major features of having the abutting portion 5 as described above. Hereinafter, the function and effect of the abutting portion 5 will be described.
FIG. 2 is a diagram (side view) showing a state in which the fastened body H is fastened by the coupling 1 of the present invention having the butting portion 5 on the flange portion 4. Since the abutting portion 5 is provided (front side outside the fastening tool 7), when the torque of the bolt of the fastening tool 7 is applied, the abutting portion 5 first comes into contact with the flange portion. 4 prevents the deformation of the tip 4 from being tapered toward the outer tip, so that the inner working diameter of the coupling 1 can be gradually reduced. That is, by providing the flange portion 4 with the abutting portion 5, the flange portion 4 at the time of tightening can be performed without increasing the plate thickness of the coupling 1 and without changing the material of the coupling 1 to a hard material. Inadvertent tilt deformation (a phenomenon in which the flange portion 4 loses) can be prevented.

Hereinafter, the fastening progress (operation mode) by the coupling 1 of the present invention will be described in detail with reference to FIG.
For example, the coupling 1 shown in FIG. 2A is formed so as to exhibit a “C” shape that is tapered toward the outer front end (opening / closing free end side) in the initial state. When the fastening tool 7 is tightened in the coupling 1 exhibiting such an initial state, the flange portions 4 and the butting portions 5 gradually approach each other, and eventually, as shown in FIG. It comes into contact with (abuts) from the tip side of the abutting portion 5. Such an approach does not cause the flange portion 4 or the abutting portion 5 to move in parallel as a whole, but rather the fastening body H (the flange portions FL1 and FL2) is present inside the coupling. In addition, the abutting portion 5 moves so as to gradually narrow the outer tip portion. Of course, even if the abutting portion 5 comes into contact, the flange portions 4 remain separated. In this specification, as shown in FIG. 2B, a state where the abutment between the abutting portions 5 has started is referred to as “a state at the time of abutment” or “at the time of abutment”. .

After that, when the tightening tool 7 is tightened by applying a normal torque T from the state of FIG. 2B, the abutting portion 5 becomes the fulcrum with the outer tip (abutting tip) of the abutting portion 5 as a fulcrum. As shown in FIG. 2 (c), the abutting portion 5 comes into contact with each other as a whole. Of course, such a rotation operation similarly proceeds in the flange portion 4, and therefore, the working diameter is narrowed inside the coupling 1, and a force F for tightening the fastened body H is generated.
Note that the state of FIG. 2C where the abutting portion 5 abuts on the whole tightens the fastening tool 7 with a prescribed torque T, and reduces the working diameter of the coupling 1 to a prescribed dimension. It is preferable that the two fastened bodies H sandwiched are fastened with a specified adhesion force, and such a state is referred to as “a specified tightening state” or “at the time of specified tightening” in this specification. Yes. Moreover, by setting it as such a state, the torque T applied to the fastener 7 can be functioned as an extremely effective force for efficiently narrowing the operating diameter of the coupling 1.
Incidentally, in this state (a specified tightening state in which the abutting portion 5 is entirely in contact), it is preferable that the flange portion (insertion hole 41) that keeps the separated state is substantially parallel, whereby the fastener 7 Is held stably.

  Thus, it is preferable that the pair of abutting portions 5 come into contact with each other when the specified tightening is performed. For this purpose, the abutting portions 5 are tapered toward the outer front end in the initial state. It is desirable to set so as to present a letter “C”. With this setting, the abutting portion 5 starts to come into contact with the outer tip as described above, and can be brought into contact with almost the entire surface at the time of specified tightening.

  Of course, the setting state of the abutting portion 5 in the initial state can be set so that the abutting portion 5 is substantially parallel as shown in FIG. Part 4 is also almost parallel). However, in this case, the abutting portions 5 come into substantially contact with each other in the abutting start state as shown in FIG. 3B as an example. ). 3B, when the specified torque T is further applied to the fastener 7 (bolt), the inside of the coupling 1 narrows so as to reduce the working diameter, so that the specified tightening is performed. In some cases, as shown in FIG. 3C, for example, the outer tip of the abutting portion 5 is somewhat opened, and almost the entire abutting portion 5 is applied when the specified tightening shown in FIG. It is conceivable that the contact state is somewhat unstable compared to the case of contact.

  Next, an example of a method for manufacturing the coupling element 2 will be described. In the description, a manufacturing method suitable for producing the coupling element 2 in large quantities at once will be described. That is, here, when manufacturing the coupling element 2, the semicircular arc-shaped portion, the flange portion 4, and the abutting portion 5 of the coupling element 2 are pressed from a metal plate material (blank material) having a certain plate thickness. Progressive which is formed and further processed into a desired three-dimensional shape while feeding the raw material W which is the original shape of the coupling element 2 while being connected to a part of the metal plate material (strip material S). The coupling element 2 is manufactured by processing (sequential feed processing). Incidentally, progressive processing itself is a well-known technique. For example, regarding the basic matters and the like, Japanese Patent Application No. 2007-23840 (Patent No. 4490881) in which the present applicant has already applied for a patent and has already acquired the right. ) Is used.

In the present embodiment, the coupling element manufacturing method is to obtain the coupling element 2 as a finished product through at least the following steps in order.
(1) “Form material preparation process” in which a blank W is formed from a metal material (coil material, etc.) having a certain thickness.
(2) “Modeling process” for forming each part of the shaped material W into a desired shape
(3) “Separation process” for separating the shaped material W formed in a desired shape from the strip material S
Hereafter, each process is demonstrated in detail based on FIG.

First, the “preparing step of the raw material” will be described.
In the “preparing step of the shaped material”, a blank material punched out so as to have a volume capable of realizing the target coupling element 2 from a metal material (coil material or the like) having a certain plate thickness is formed into the shaped material W. Here, in the central part of the strip material S, a spine-shaped crosspiece portion B that holds the raw material W oppositely is formed, and the raw material W is opposed to the crosspiece portion B. The blank is removed.
In the progressive processing, it is necessary to correctly determine the position of the semi-finished product (raw material W) in order to execute each process. For this reason, a positioning reference hole (pilot hole PH) is opened in the crosspiece portion B. The opening timing is opened at an initial stage of processing, for example, prior to blanking or in conjunction with blanking.

Hereinafter, the blank shape of the shaped member W in FIG. 4 will be described.
In FIG. 4, the semicircular arc-shaped portion of the coupling element 2, the flange portion 4, and the abutting portion 5 are all formed in the shape of an elongated piece (blank removed) that is continuous in a flat developed shape. The raw material W is connected to the crosspiece portion B at the portion to which the connecting member 3 is fastened in the state of the finished coupling element 2. In addition, the shaped member W is formed in a circular arc shape in a plan view at the front end portion not connected to the crosspiece portion B, and this is formed in the abutting portion 5. Furthermore, the base material W is formed with a projecting portion projecting in the lateral direction (the feeding direction of the strip material S in progressive processing) in the middle of the long and slender piece (position near the tip). These are parts for hitting the boundary between the semicircular arc-shaped portion of the coupling element 2 and the flange portion 4 and bending the flange portion 4 from the semicircular arc-shaped portion.

In the present embodiment, the abutment portion 5 formed on the outer side of the flange portion 4 is within the width dimension of the clamping surface 20 of the coupling element 2 in a flattened state in the “preparing step of the base material”. It is a big feature that it is punched. Here, the “width (dimension)” refers to the feeding direction of the strip material S (raw material W) in progressive processing.
And the manufacturing method of the conventional coupling element can be followed by the said structure (with the width dimension of the butting | pinching part 5 being less than the width dimension of the clamping surface 20 in a planar expansion | deployment state). That is, the material removal, shape processing, and the like of the coupling element 2 can be performed in the same manner as in the past (coupling element that does not have the abutting portion 5) without significant process change. For example, compared with the conventional material removal, when the blank material is punched by the amount of the abutting portion 5, the material W (coupling element 2) is extended in the longitudinal direction (the direction orthogonal to the progressive feed direction). Therefore, there is no need to change the workpiece transfer direction (width direction) in progressive machining. In addition, it is not necessary to change the installation interval of the conventional pressing mold described later, so that the conventional progressive processing (press processing) can be substantially followed, and there is an extraordinary effect that no significant process change is involved.

Next, the “modeling process” will be described.
The “modeling process” is a process in which the raw material W is sandwiched between a pair of opposed molds (press molds), and each part of the raw material W is three-dimensionally formed into a desired three-dimensional shape. The base material W is three-dimensionally formed in a semicircular arc shape, and the clamping surface 20 that sandwiches the flanges of the fastened body H is formed in a slope shape having a V-shaped cross section or a mountain-shaped cross section. Similarly, the flange portion 4 and the abutting portion 5 are also three-dimensionally formed in a desired three-dimensional shape.

As shown in FIG. 4, the “modeling process” is generally divided into a plurality of stages, for example, a first modeling process, a second modeling process, a third modeling process, and the like. The more complex the solid, the more modeling steps it can be divided into. And the desired shape is gradually given to the original shape material W through this several modeling steps sequentially. Of course, when the modeling process is divided into a plurality of stages, a plurality (pairs) of a pair of opposed molds sandwiching the raw material W are provided according to each modeling process stage.
Incidentally, here, in the initial stage of the “modeling process”, the semicircular arc-shaped portion of the coupling element 2 is formed on the raw material W, and then the inclined surface of the clamping surface 20 inside the coupling element is formed in the next modeling stage. Three-dimensional formation is made. Furthermore, the flange part 4 and the abutting part 5 are shape | molded in the modeling step after that. In addition, for this reason, in the plan view of FIG. 4, the width dimension of the raw material W (coupling element 2) is apparently gradually reduced as the molding process proceeds. .
Here, the above-mentioned “width (dimension)” refers to the dimension in the feed direction of the strip material S (raw material W) in the progressive processing as described above, and this is the “width dimension of the abutting portion”, The same applies to terms such as “width dimension of clamping surface”.

  Further, the boundary portion (so-called throttle portion) that bends the flange portion 4 from the semicircular arc-shaped portion of the coupling element 2 is formed in an arc shape in plan view as shown in FIGS. 4 and 5A. It is preferable that the press workability can be improved and a desired shape can be realized without difficulty. In particular, in the present invention, since the abutting portion 5 is further provided for the flange portion 4, the abutting portion 5 is formed as described above, so that the abutting portion 5 protrudes from the semicircular arc-shaped portion of the coupling element 2 and further from the flange portion 4. The contact part 5 can be processed smoothly. Of course, as shown in FIG. 5B, for example, the diaphragm portion can be formed in a substantially flat shape in a plan view, but in this case, it is somewhat more than in the case of a circular arc shape in a plan view. Or press workability may be reduced.

Next, the “separation process” will be described.
The “separating step” is a step of separating the raw material W, in which each part is three-dimensionally formed into a desired three-dimensional shape by the modeling process, from the strip material S (crosspiece part B).
In this embodiment, the insertion hole 41 through which the fastener 7 is passed is also opened at a stroke in this separation process, but this opening can also be performed during the modeling process.

Thereafter, the shaped material W (coupling element 2) separated from the strip material S is appropriately subjected to burr removal and surface polishing.
For example, the coupling element 2 and an additive called a medium are placed in a barrel container, and the barrel container is rotated or vibrated to collide the coupling element 2 with the medium to perform deburring or surface polishing. It is.

  In the above description, the progressive processing for blanking the raw material W while the raw material W is connected to the strip material S when the raw material W is obtained has been described. However, in obtaining the shaped material W, it is possible to obtain the shaped material W by completely separating the shaped material W one by one from the metal plate material, or individual blanks that have already been separated. It is also possible to apply the material as the raw material W. However, in such a case, a so-called transfer mechanism is separately used in order to send each separated shaped member W to each subsequent press machine (opposite type).

Next, the to-be-fastened body H fastened with the coupling 1 of this invention is demonstrated.
As described above, the fastened body H includes a bearing housing that rotatably supports a turbine rotor in a turbocharger used in an automobile engine, and a turbine housing that covers the periphery of a turbine wheel provided at one end of the turbine rotor. A combination can be an object. Here, the turbocharger is a supercharger that is used as a means for increasing the output and performance of an automobile engine. The turbocharger drives the turbine rotor by the exhaust energy of the engine, and the compressor by the output of the turbine rotor. Is a device that brings the engine to a supercharged state that is higher than that of natural intake.

As an example, this type of turbocharger TC is provided with a turbine housing H2 and a compressor housing H3 so as to sandwich a bearing housing (center housing) H1 that rotatably supports the turbine rotor R, as shown in FIG. ing. Here, the turbine housing H2 is a casing member that covers the periphery of a turbine wheel TW (an impeller that rotates by the force of exhaust gas) provided at one end of the turbine rotor R, and the compressor housing H3 is another member of the turbine rotor R. It is a casing member which covers the circumference | surroundings of the compressor wheel CW (compressor impeller) provided in one end (other end).
In addition, the turbocharger T for automobiles is repeatedly exposed to a harsh environment of high temperature and exhaust gas, and also has a wide range of operating temperatures. In general, the bearing housing H1 and the turbine housing H2 are often formed of different materials, and therefore, the two housings have different expansion coefficients when receiving heat (at a high temperature). In this respect, since the coupling 1 of the present invention can continue to fasten the fastened body H with a strong adhesion force (axial force) over a long period of time, the bearing housing H1 can be used even in the above severe environment. And the turbine housing H2 are firmly tightened, and it is possible to prevent a situation in which both the housing portions fastened during use are loosened and the exhaust gas is leaked from here.

  Of course, the fastened body H is not limited to the bearing housing H1 and the turbine housing H2 in the turbocharger TC, and any connecting member can be applied as the fastened body H. Specifically, it is possible to fasten exhaust system members such as automobile exhaust pipes, or not only such automobile-related members, but also fastening of various separated members, for example, pipe members Or the like can be used as the fastened body H. However, the body to be fastened H has flanges FL1 and FL2 projecting to the outer peripheral side, and is fastened by the coupling 1 of the present invention in a state where they are brought into contact with each other in a face-to-face manner.

[Other Examples]
The present invention has the above-described embodiment as one basic technical idea, but the following modifications can be considered.
First, in the basic embodiment described above, the abutting portion 5 is formed so as to be folded back in two stages from the tip portion of the flange portion 4, and the flange portion 4 tip to the abutting portion 5 have a crank shape. . However, the abutting portion 5 does not necessarily have to be formed on the distal end side of the flange portion 4. For example, as shown in FIG. 1D, the abutting portion 5 protrudes to the side of the flange portion 4. It may be formed. In other words, the abutting portion 5 may be provided on the outer front side of the fastener 7.

  Further, in the basic embodiment described above, the abutting portion 5 has a configuration in which the surfaces formed by folding the raw material W from the flange portion 4 with the plate thickness abut each other. However, the abutment of the abutting portion 5 is not necessarily the abutment between the surfaces. For example, as shown in FIG. Is also possible. In this manner, the abutting portion 5 can be formed so as to be folded only once at the tip end portion of the flange portion 4, and the abutting portion 5 can be realized by the plate thickness of the raw material W (non-crank shape). In this case, it is preferable that the burrs of the plate thickness portion (abutting portion 5) to be contacted are removed cleanly to realize accurate abutting setting.

DESCRIPTION OF SYMBOLS 1 Coupling 2 Coupling element 20 Holding surface 3 Connecting member 4 Flange part 41 Insertion hole 5 Abutting part 7 Fastening tool

TC Turbocharger R Turbine rotor TW Turbine wheel CW Compressor wheel H1 Bearing housing (center housing)
FL1 buttock H2 turbine housing FL2 buttock H3 compressor housing

H Fastened object W Shape material S Strip material B Crosspiece part PH Pilot hole

T torque F force

Claims (7)

In a state where the flanges formed at the ends of the fastened bodies are in contact with each other, by sandwiching the flanges, the coupling is configured to fasten the two fastened bodies,
This coupling includes a pair of coupling elements having a semicircular arc shape, and is configured such that one end of each coupling element is fastened with a connecting member so that the other end can be opened and closed. On the open / close end side, a flange portion protruding outward is formed, and a fastener such as a bolt or nut is provided on this flange portion,
The flange portion is provided with an abutting portion on the outer side of the fastener, and the flange portion is in a separated state when the coupling is tightened. ring.
The coupling according to claim 1, wherein the abutting portion is provided so as to be positioned at least at an outer end of the flange portion.
In the coupling element, the clamping surface for clamping the flange portion of the body to be fastened is formed in an inclined shape having a V-shaped cross section or a mountain shape in cross section, and the fastened bodies are more firmly attached to each other as the fastener is tightened. Is configured to let
The coupling according to claim 1, wherein a width dimension of the abutting portion is formed within a width dimension of the holding surface in a planar development state.
The coupling according to any one of claims 1 to 3, wherein the abutting portion is configured by abutting surfaces formed by folding back from a flange portion.
A bearing housing that rotatably supports a turbine rotor in a turbocharger used in an automobile engine and a turbine housing that covers the periphery of a turbine wheel provided at one end of the turbine rotor are applied as the fastened body. The coupling according to any one of claims 1 to 4, wherein the coupling is characterized in that:
6. The coupling according to claim 4, wherein the pair of abutting portions are set in a letter “C” shape that narrows toward the outer front end in an initial state.
A pair of semicircles constituting a coupling that fastens two fastened bodies by sandwiching the fastened parts in a state where the fastened parts formed at the ends of the fastened bodies are in contact with each other. In producing an arcuate coupling element,
One end of the coupling element is fastened with a connecting member, and the other end side is configured to be openable and closable.
In addition, the flange portion is provided with an abutting portion on the outer side,
In manufacturing the coupling element, it is performed by progressive processing to process the original shape material of the coupling element into a desired three-dimensional shape while being sequentially fed while being connected to a part of the metal plate material,
The manufacturing process is
A blank forming material that is punched to have a volume capable of realizing a desired coupling element from a metal material having a constant plate thickness, and a preform forming step,
The shape material is sandwiched between a pair of opposed molds, at least the shape material is formed in a semicircular arc shape, and the sandwiching surface for sandwiching the flanges of the fastened bodies is formed in a V-shaped cross section or a slope shape having a mountain shape. Modeling process to do,
Comprising a separate step of separating the shaped material after the shaping step from the metal plate,
In addition, in the step of preparing the base material, the abutting portion formed on the outer side of the flange portion is punched out within the width dimension of the clamping surface in a flattened state.

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