This invention relates generally to a beaded conduit joint, sometimes referred to as “Marmon” conduit couplings, and more particularly to improved beaded couplings and methods for forming beaded couplings in conduit blanks.
Joining conduits is common in many products and systems, including vehicle engine exhaust systems. Beaded couplings (or “joints”) are used to connect two conduits or other components. Beaded couplings are well known and include a first conduit having an end portion on which an outwardly extending annular flange is formed, and a second conduit having a flared end for mating with the annular flange. Once fitted together, the two conduits are releasably joined using a clamp that engages both the annular flange and the flared end to secure the two conduits together.
Various modifications to beaded couplings are known that improve various aspects of the couplings, but they all face similar obstacles in the manufacturing process. For example, mating faces of the outwardly extending annular flange and the flared end must match well enough to resist leaking and other failures. Gaskets between mating faces and in the clamp can be used, but tolerances must still be tight and consistent in high-performance applications.
Known manufacturing techniques for forming beaded couplings can result in poor fits and leaks between conduits. This is especially true in high pressure and temperature applications, such as engine exhaust systems where tolerances are tight. For example, some forming methods result in annular flanges with irregular profiles, tooling marks on sealing faces, and excessive thinning of
Conduit material at the outwardly extending annular flange and at the flared end of the mating conduit.
The annular flange and the flared end were typically formed by using an indexing/sizing machine having a multi-hit ram that forms and sizes the annular flange on one piece and a flared end on a mating piece of the coupling. The ram can change the thickness of the material in the formed profile, and the parts typically are not formed to “full print geometry,” which is a term used to describe products with material extending fully into tight corners or recesses of forming dies. Such full print geometry products are difficult to obtain, especially with traditional index/sizing machines. Parts that do not have full print geometry may not be within manufacturing specifications and may even have wall thicknesses that are too thin because the wall material was stretched toward the extreme corners or recesses of the forming dies. To minimize the problems with thinning of the conduit wall material and related failures, the conduit walls are typically thick enough to compensate for the particular forming method being used, but the parts can still be outside of manufacturing tolerances when such manufacturing techniques are used. These prior manufacturing methods also leave noticeable tooling mark on the parts.
Additional complications in forming beaded couplings are apparent when one or both of the conduits is bent to form an elbow or is part of a component. In some situations to aid in manufacturing, a straight section of conduit is welded to an elbow after the beaded coupling elements are formed on a straight section. This additional step adds time and cost.
Thus, there is a need for a beaded coupling manufacturing method that reduces tooling marks, minimizes flaws from conduit thinning, has consistent results, and can be used with elbow conduits or when other components are connected to the conduit in advance.
The present invention is directed to methods for forming an annular flange on one section of conduit for use in a beaded coupling. Once such method in accordance with the present invention includes the steps of: positioning a conduit blank in a die; restraining the conduit blank with a die having an annular flange recess formed therein; inserting a flexible material such as an elastomer inside the first conduit; and applying an axial compression force to the flexible material to cause a radially outward expansion of the flexible material, force a portion of the conduit blank outwardly into engagement with the annular flange recess formed in the die, and thereby form a conduit with an annular flange.
Once the annular flange is formed, an additional step of trimming an end of the conduit can be performed. Using an extended conduit helps maintain the flexible material in the conduit to protect the flexible material during conduit forming. After the forming of the annular flange using the protected flexible material, the conduit can be trimmed to finished length and the flexible material can be reused.
Further, the present invention can also be used to ensure a more uniform wall thickness at the extreme outer reaches of the tooling die by allowing at least a portion of the conduit blank to move axially. Axial movement is possible by restraining only a portion of the conduit blank in the die, while allowing another portion of the conduit blank to move slightly in an axial direction. In this way, the annular flange is formed without substantially stretching the conduit blank wall into the die annular flange recess extremities, and instead the annular flange is formed from material that is nearly full thickness.
A method for forming a conduit with an annular flange for forming part of a beaded coupling, the method comprising the steps of positioning a conduit blank in a split forming die having a first die half defining a first portion of a radially extending annular recess, and a second die half defining a second portion of a radially extending annular recess, wherein the first die half and the second die half are initially spaced apart inserting a flexible material in the conduit blank; moving the first die half toward the second die half and compressing the flexible material to force the flexible material against the conduit blank and force a portion of the conduit blank outward into engagement with the first portion of a radially extending annular recess and the second portion of a radially extending annular recess.
Such a process forms an annular flange to within manufacturing tolerances of specified dimensions (“print profile”) with minimal tooling marks and with minimal thinning of the conduit material. This process can be used on a previously formed (bent) tube or conduit, which is more efficient than forming only straight sections of conduit that are later welded to a formed section of conduit or tube.
In the following detailed description of drawings, the same reference numeral will be used to describe the same or similar element in each of the figures. Further, the elements in the figures are oriented horizontally, but they can be arranged vertically or in any other desired orientation in the present invention.
Illustrated in
Joined to the upper clamp 204 is an upper die holder 230, and joined to the lower clamp 206 is a lower die holder 232. The die holders 230 and 232 hold dies 120 that are described in detail below.
Actuator controls 236 are used to control movement and timing of the upper clamp actuator 208, the lower clamp actuator 210, and the energizer actuator 212.
The frame 202 includes a top 240, a bottom 242, and two sides 246, all joined together using connectors 248 suitable to hold the frame 202 together under actuator forces as high as 230,000 pounds, and outward pressures of about 30,000 pounds per square inch (“psi”), for example.
With reference to
The annular flange 22 includes first and second side surfaces 26, 28, and an interior surface 29 extending radially outwardly from a base surface 32 of the conduit 20. The side surfaces 26, 28 preferably converge as they extend radially outwardly from the base 32. A portion of the annular flange 22 that includes the surfaces 26 and 28 can be frustoconical in cross-section, but other shapes are possible as well, and are within the definition of an annular flange or bead, as those terms are used herein.
As seen in
Steps of a manufacturing method in accordance with the present invention are illustrated in
To form a radial flange in the conduit 20, the conduit blank 20 is disposed in the forming die 80 with the end portion 24 extending beyond (to the right of) the forming die 80. Preferably, at least a portion of the conduit blank 20 is unrestrained, so that the unrestrained portion can move axially when pressure is applied to form the annular flange 22. The conduit blank 20 is illustrated as being cylindrical and straight, but other shapes are possible including a conduit 20 with a bent portion that would be positioned to outside of the forming die 80 (to the left as illustrated).
The forming die 80 is formed in at least two portions (split), but it can have any number of portions that are separable so that a completely formed conduit with an annular flange 22 can be removed after forming.
The forming die 80 has formed therein the annular recess 82 machined to any desired shape and tolerance to form the radially extending annular flange 22.
The fixed reaction post 90 is disposed in the conduit blank 20 so that the rounded end 94 matches an internal diameter of the conduit 20. The shaft 92 of the reaction post 90 as a smaller external diameter compared to the internal diameter of the conduit 20. An annular space 114 is defined between the reaction post shaft 92 and the conduit blank 20.
The elastomer material 102 is disposed in the annular space 114 where it will be compressed by the energizing sleeve 110 with about 90,000 of force, for example, but a wide range of forces is possible and can be determined based on the forming pressures needed for a given part's material properties and the desired final shapes of the parts. Preferably, the elastomer material 102 is a black polyurethane rod of suitable dimensions to match the inside diameter of the beaded joint, and have a Durometer hardness of about 90, for example, but other Durometers can be used depending on the amount of force necessary to form the parts and to avoid damaging the elastomer so it can be reused. The elastomer 102 can be damaged when it is too soft because it can flow around the wedges and rams and also stick to the parts being formed. If too rigid, the elastomer 102 may not be resilient enough to be returned to a desirable shape for use in subsequent forming operations. The elastomer described herein is a preferred embodiment, but any material that is flexible enough to move into recesses in a die and retain most of its volume, so it cannot be compressed to the point where it fails to transmit the required conduit forming loads, is acceptable and within the definition of “flexible material,” as used herein. The elastomer material 102 will be under intense pressure during the compressing step (
The energizing sleeve 110 is driven by a hydraulic post that can apply an axial force of as about 90,000 pounds to the elastomer material 102. The elastomer material 102 translates the axial force to a radial outward pressure against the conduit blank 20 to form the annular flange 22. The radial outward pressure is preferably about 30,000 psi, but the actual pressure needed depends on the material properties of the part being formed and the shapes into which the part will be formed.
The first step of the manufacturing method is illustrated in
In
After the energizing sleeve 110 is released and moves back toward the right (as illustrated in
An optional additional step is illustrated in
If desired, the conduit end portion 24 can be further shaped, as in the example of a diameter-reducing process illustrated in
Steps of an alternate manufacturing method in accordance with the present invention are illustrated in
To form an annular flange 22 in the conduit 20, the conduit blank 20 is disposed in the forming die 80 with the end portion 24 extending toward the right of the forming die 80 (
As in the above example, the forming die 80 is formed in at least two portions (split), but it can have any number of portions that are separable so that a completely formed conduit 20 with an annular flange 22 can be removed after forming.
The forming die 80 has formed therein the annular recess shape 82 machined to any desired shape and tolerance to form an annular flange 22.
The energizing post 190 is disposed in the conduit blank 20, so that the rounded end 194 matches an internal diameter of the conduit 20. The shaft 192 of the energizing post 190 as a smaller external diameter compared to the internal diameter of the conduit 20. An annular space 114 is defined between the energizing post shaft 192 and the conduit blank 20.
The elastomer material 102 is disposed in the annular space 114 where it will be compressed by a force as described above, by the energizing post 190 moving toward the right, as illustrated. The elastomer material 102 will be under intense pressure during the compressing step (
The first step of this embodiment of the manufacturing method is illustrated in
In
After the energizing post 190 is released and moves back toward the left (as illustrated in
Another exemplary embodiment of the present invention is illustrated in
In this embodiment, the two die halves 300 and 302 move toward one another at the same time force is applied to the elastomer material 102, so that both the die movement and the elastomer compression are synchronized to form the annular flange 22. One or both of the die first half 300 and the die second half 302 are movable in an axial direction of the conduit 20 to make contact with one another, as illustrated in
Another exemplary embodiment of the present invention is illustrated in
In this embodiment, the two die halves 300 and 302 move toward one another at the same time force is applied to the elastomer material 102, so that both the die movement and the elastomer compression are synchronized to form the annular flange 22. One or both of the die first half 300 and the die second half 302 are movable in an axial direction of the conduit 20 to make contact with one another, as illustrated in
The die first half 300 defines half of an annular recess 306 and the die second half 302 defines a mating half of an annular recess 308, so that when the die first half 300 is adjacent to the die second half 302, a complete annular recess is defined by the two halves 306 and 308, as seen in
In a manufacturing method of this embodiment, according to the present invention, the conduit blank 20 is placed in the die first half 300 and the second die half 302. Each die half 300 and 302 is itself split longitudinally to enable the removal of a formed beaded conduit 20, but the longitudinal split is not visible in figures. The elastomer material 102 is prepared with sealing wedges, as described above, and an energizing sleeve is forced against the elastomer material 102, in the manner described above to translate the axial load of the energizing sleeve into a radial outward pressure applied by the elastomer material 102.
As the radial outward pressure applied by the elastomer material 102 causes the conduit blank 20 to expand outwardly, the die first half 300 is moved toward the die second half 302 in a preferably synchronized manner, so that the die halves 300 and 302 meet at about the same time as (or slightly ahead of) the full movement of the elastomer material 102 to complete formation of the annular flange 22.
Preferably, the tube blank 20 is at least partially unrestrained by the die halves 300 and 302 to permit movement of the tube blank 20 in an axial direction as the annular flange 22 is being formed. Preferably, the die half 302 does not restrain axial movement of the conduit blank 20, but either or both of the die halves 300 and 302 can move relative to the conduit blank 20. In this manner, the tube blank 20 wall at the location of the radial flange 22 does not need to stretch and become thin when the annular flange 22 is formed because the axial length of the conduit blank 20 shortens to accommodate material movement outward to form the annular flange 22.
Another exemplary embodiment of the present invention is illustrated in
In this embodiment, the two die halves 400 and 402 move toward one another at the same time that force is applied to the elastomer material 102, so that both the die movement and the elastomer compression cooperate to form the annular flange 22. One or both of the die first half 400 and the die second half 402 are movable in an axial direction of the conduit 20 to make contact with the central die retainer 404, as illustrated in
The die first half 400 defines a portion of an annular recess 406, the die second half 402 defines a mating portion of an annular recess 408, and the central die retainer 404 defines the final portion of the annular recess 408, so that when the die first half 400 and the second die half 402 are adjacent to the central die retainer 404, a complete annular recess is defined, as seen in
In a manufacturing method of this embodiment, according to the present invention, the conduit blank 20 is placed in the die first half 400 and the second die half 402. Each die half 400 and 402 is itself split longitudinally to enable the removal of a formed beaded conduit 20, but the longitudinal split is not visible in figures. The elastomer material 102 can be prepared with sealing wedges, as described above, and an energizing sleeve or a ram can be forced against the elastomer material 102, in the manner described above to translate the axial load of the energizing sleeve or ram into a radial outward pressure applied by the elastomer material 102.
As the radial outward pressure applied by the elastomer material 102 causes the conduit blank 20 to bend and expand outwardly, the die first half 400 is moved toward the die second half 402 (or vice versa) in a synchronized manner, so that the die halves 400 and 402 meet at the central die retainer 404 at about the same time as (or slightly ahead of) the full movement of the elastomer material 102 to complete formation of the annular flange 22. The central die retainer 404 prevents the annular flange 22 from being pinched between the die halves 400 and 402. The central die retainer 404 can also be used to impart a shape on the annular flange 22 that would not otherwise be possible by simply using two die halves.
Preferably, the tube blank 20 is at least partially unrestrained by the die halves 400 and 402 to permit movement of the tube blank 20 in an axial direction as the radial flange 22 is being formed. Preferably, the one (or both) die half 402 does not restrain axial movement of the conduit blank 20, but either or both of the die halves 400 and 402 can move relative to the conduit blank 20. In this manner, the tube blank 20 wall at the location of the radial flange 22 does not need to stretch and become thin when the annular flange 22 is formed because the axial length of the conduit blank 20 shortens to accommodate material movement outward as the annular flange 22 is formed.
There can be some material stretching and thinning with the present embodiment, but the material will not be thinned as much as with other methods. By retaining more conduit wall thickness, the annular flange 22 is more robust than an annular radial flange with a thinner wall. Using die halves 300 and 302 (or 400 and 402) can even enable compression of the conduit 20 wall at the annular flange 22 so that the thickness of the wall can actually increase to create an even more robust annual flange 22.
It should be apparent to those of ordinary skill in the art that the at least one embodiment can be modified without departing from the principles thereof, and no unnecessary limitations from the preceding description should be read into the following claims.
Number | Name | Date | Kind |
---|---|---|---|
2458854 | Hull | Jan 1949 | A |
3627336 | Lawson | Dec 1971 | A |
4006619 | Anderson | Feb 1977 | A |
4068372 | Kamohara | Jan 1978 | A |
4685191 | Mueller | Aug 1987 | A |
5233855 | Maki | Aug 1993 | A |
8528377 | Ohara | Sep 2013 | B2 |
Number | Date | Country | |
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20170028457 A1 | Feb 2017 | US |