Wire mesh rivet

Abstract

A wire mesh rivet (13) is provided which is used to produce a wire mesh isolator (11) in a bore (9) of a substrate such as a heat shield (7) for a vehicle exhaust system. The rivet (13) comprises a unitary wire mesh structure (19) which has a collar (15) and a shank (17). The collar (15) has a higher density than the shank (17), e.g., the collar (15) has the density of the finished isolator (11). The rivet (13) is formed into the finished isolator (11) by compressing the shank (17) to form a second collar, while restraining the original collar (15) from substantially changing its shape. The rivet (13) can include a metal insert (23) which prevents the wire mesh of the finished isolator (11) from experiencing high levels of compression when the substrate is fastened to its supporting structure. The rivets (13) can be carried by a dispensing strip (31) and can be formed into the finished isolator (11) using forming equipment (39) whose dimensions are compatible with the limited space available with some substrates.

Claims

1. A method for making a wire mesh preform comprising: (I) providing a wire mesh tube having a central bore; and (II) forming the tube into a wire mesh preform which comprises a unitary wire mesh structure which has a central bore and consists of a collar at one end thereof and a shank at the other end thereof, said forming comprising: (a) supporting the tube by: (i) inserting a first portion of the tube into a first cavity, said first cavity having a fixed bottom and a moveable wall; and (ii) inserting an arbor into the tube's bore; (b) surrounding a second portion of the tube with a second cavity; (c) reducing the volume of the second cavity to form the structure's collar by compressing the second portion of the tube, while not substantially reducing the volume of the first cavity; and (d) reducing the volume of the first cavity through movement of the moveable wall relative to the fixed bottom to form the structure's shank by compressing the first portion of the tube; wherein the second portion of the tube is compressed to a greater extent than the first portion of the tube so that the density of the collar is greater than the density of the shank.

2. The method of claim 1 wherein the moveable wall is spring-loaded.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a perspective view of representative heat shields with which wire mesh isolators are used.

(2) FIG. 2 is a perspective, cross-sectional view of a wire mesh rivet constructed in accordance with certain aspects of the invention.

(3) FIG. 3 is a cross-sectional view of a wire mesh rivet wherein the rivet includes a metal insert in the form of a grommet and the grommet includes barbs which engage the rivet's wire mesh structure.

(4) FIG. 4 is a cross-sectional view of a wire mesh rivet wherein the rivet includes a metal insert in the form of a grommet and the grommet includes apertures which engage the rivet's wire mesh structure. As shown in this figure, the apertures extend through the entire thickness of the wall of the insert.

(5) FIG. 5 is a cross-sectional view of a wire mesh rivet wherein the rivet includes a metal insert in the form of a sleeve and the sleeve includes apertures which engage the rivet's wire mesh structure. As shown in this figure, the apertures extend through the entire thickness of the wall of the insert.

(6) FIG. 6 is a cross-sectional view of a wire mesh rivet wherein the rivet includes a metal insert that includes apertures which extend through the entire thickness of the wall of the insert. The figure illustrates the engagement of wire mesh with an aperture.

(7) FIGS. 7A and 7B are cross-sectional and top view views, respectively, of a metal insert in the form of a grommet which includes apertures which extend partially through the thickness of the wall of the insert.

(8) FIG. 8 is a perspective view of a dispensing strip carrying wire mesh rivets.

(9) FIG. 9 is a top view of the dispensing strip of FIG. 8 showing the flexible fingers used to engage the shanks of the mesh rivets.

(10) FIG. 10 is a perspective view illustrating equipment for forming a wire mesh isolator from a wire mesh rivet at a bore of heat shield.

(11) FIG. 11 is a perspective view of a portion of the isolator forming equipment of FIG. 10 with various parts removed to highlight features of the equipment's lower positioning assembly.

(12) FIG. 12 is a side view, partially in section, of a portion of the lower positioning assembly of the isolator forming equipment of FIG. 10.

(13) FIG. 13 is a cross-sectional view of a portion of the upper forming assembly of the isolator forming equipment of FIG. 10.

(14) FIG. 14 is a side view illustrating the use of a dispensing strip to provide wire mesh rivets to the isolator forming equipment of FIG. 10. Various parts have been removed for clarity.

(15) FIG. 15 is a perspective view showing the formation of multiple isolators in a heat shield without the need to reposition the part.

(16) FIGS. 16A and 16B are perspective cross-sectional views of examples of wire mesh isolators produced from wire mesh rivets.

(17) FIG. 17 is a cross-sectional view showing a tool for forming a wire mesh tube into a wire mesh rivet. The tool is in its open position in this figure.

(18) FIG. 18A is a cross-sectional view showing the tool of FIG. 17 in its initial closed position. FIG. 18B is a cross-sectional view showing the configuration of the wire mesh tube at this point in the process.

(19) FIG. 19A is a cross-sectional view showing the configuration of the tool of FIG. 17 at the point where the rivet's collar has been formed. FIG. 19B is a cross-sectional view showing the configuration of the wire mesh tube at this point in the process.

(20) FIG. 20A is a cross-sectional view showing the configuration of the tool of FIG. 17 at the point where both the rivet's collar and its shank have been formed. FIG. 20B is a cross-sectional view showing the configuration of the wire mesh tube at this point in the process, i.e., it shows the completed wire mesh rivet.

(21) The reference numbers used in the drawings refer to the following:

(22) 7 heat shield

(23) 9 bore in substrate (e.g., heat shield)

(24) 11 assembled wire mesh isolator

(25) 13 wire mesh rivet

(26) 15 collar of wire mesh rivet

(27) 17 shank of wire mesh rivet

(28) 19 unitary wire mesh structure of wire mesh rivet

(29) 21 bore of unitary wire mesh structure

(30) 23 metal insert

(31) 24 metal insert collar

(32) 25 barb on metal insert

(33) 27a aperture which extends through entire thickness of wall of metal insert

(34) 27b aperture which extends partially through thickness of wall of metal insert

(35) 29 wire mesh in aperture of wall of metal insert

(36) 31 dispensing strip

(37) 33 apertures in dispensing strip

(38) 35 flexible fingers of dispensing strip

(39) 37 slits of dispensing strip

(40) 38 feed notches of dispensing strip

(41) 39 isolator forming equipment

(42) 41 forming assembly of isolator forming equipment

(43) 43 positioning assembly of isolator forming equipment

(44) 45 mandrel of positioning assembly

(45) 47 sleeve of positioning assembly

(46) 49 recess of sleeve of positioning assembly

(47) 51 mandrel of forming assembly

(48) 53 tamp of forming assembly

(49) 55 sleeve of forming assembly

(50) 55 cavity formed by inner wall of sleeve of forming assembly

(51) 57 sensor of forming assembly

(52) 59 wires for sensor

(53) 61 supporting structure for isolator forming equipment

(54) 63 second collar of wire mesh isolator

(55) 65 substrate

(56) 67 fastener

(57) 69 exhaust system component

(58) 70 rivet forming tool

(59) 71 arbor of rivet forming tool

(60) 73 rolled mesh tube

(61) 75 upper forming sleeve of rivet forming tool

(62) 77 stationary member of rivet forming tool

(63) 79 spring-loaded sleeve of rivet forming tool

(64) 81 first cavity of rivet forming tool

(65) 83 second cavity of rivet forming tool

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

(66) As discussed above, in connection with certain of its aspects, the invention provides wire mesh rivets for use in forming wire mesh isolators. FIG. 2 shows a representative configuration for such a rivet. As shown in this figure, the rivet comprises a unitary wire mesh structure 19 which (a) has a bore 21 and (b) comprises a collar 15 and a shank 17. The unitary wire mesh structure is preferably formed from a continuous piece of wire mesh, although multiple pieces can be united to form the unitary structure if desired.

(67) As shown in, for example, FIGS. 3-7, mesh rivet 13 preferably includes a metal insert 23 which extends partially along central bore 21. Metal insert 23 may be in the form of a grommet which has a collar which engages the collar of the unitary wire mesh structure (see FIGS. 3, 4, 6, and 7) or a simple sleeve without a collar (see FIG. 5). In either case, the primary function of the metal insert is to prevent the wire mesh from being excessively compressed when a heat shield is installed in a vehicle. As shown in FIG. 16, such installation involves the insertion of a fastener 67 through the bore of the assembled isolator and the tightening of the fastener to a component of the vehicle, e.g., to a component of the vehicle's exhaust system. To ensure that the heat shield does not become loose during use, substantial torque is typically applied to the fastener. Accordingly, the wall of the metal insert needs to have sufficient column strength to withstand the resulting compressive forces.

(68) Although the metal insert can simply be placed within the bore of the unitary mesh structure, preferably, the metal insert engages the mesh structure so as to minimize chances that the insert will separate from the mesh structure during shipment and handling of the rivet and/or the assembled isolator prior to final installation of the heat shield. FIG. 3 shows the use of barbs 25 on the outside surface of the metal insert for this purpose. Although the barb approach works satisfactorily, it is relatively expensive since a substantial amount of metal (e.g., on the order of 80%) needs to be removed from the part to form the barbs.

(69) FIGS. 4-7 shows an alternate approach for retaining a metal insert in the unitary mesh structure that is substantially less expensive in terms of material costs than the barb approach of FIG. 3. In accordance with this approach, at least two apertures 27 are formed in the outer surface of the wall of the metal insert. During manufacture of the rivet (see below), wire mesh enters into the apertures (see, for example, reference number 29 in FIG. 6) and thus substantially locks the insert and the sleeve together.

(70) The apertures can extend completely through the wall of the metal insert as shown by reference number 27a in FIGS. 4-6 or only partially through the wall as shown by reference number 27b in FIG. 7. The apertures that extend completely through the wall can be produced by piercing the wall, while the apertures that extend partially through the wall can be produced by broaching.

(71) Broaching is generally less expensive than piercing. Also, because the broached apertures only extend partially through the insert's wall, the wall retains more of its original column strength which, as discussed above, is important in terms of withstanding the compressive forces applied to the insert during fastening of a heat shield to its supporting structure. For both these reasons, apertures that extend only partially through the wall of the insert are generally preferred.

(72) The average wire mesh density of the mesh rivet's collar is greater than the average wire mesh density of its shank. In particular, the average density of the collar is substantially equal to the average density of the finished isolator, while the average density of the shank is substantially less than the finished density. In this way, after being inserted in the bore of a substrate (e.g., a bore in a heat shield), the shank can be compressed to form a second collar which has the density of the finished isolator (see below).

(73) Quantitatively, the ratio of the average density of the rivet's shank to the average density of the rivet's collar is in the range of 1:2 to 1:3, preferably in the range of 1:2 to 1:2.5, and most preferably, approximately 1:2. The density of the collar will depend on the particular application, but generally, when expressed in percent, the average density of the rivet's collar is in the range of 15% to 25%. Accordingly, the density of the shank will generally be in the range of 7.5% to 12.5%. Preferred collar and shank densities are approximately 20% for the collar and approximately 10% for the shank.

(74) As known in the art, the average density (D) in percent of a wire mesh part can be calculated by: (1) determining the weight (W) of the part, (2) determining the volume (V) of the part, (3) determining the density () of the wire making up the wire mesh, and (4) calculating the average density from the equation: D=100*(W/(V*)).

(75) The difference in density between the rivet's collar and shank can be achieved using tooling of the type shown in FIGS. 17-20. FIG. 17 shows tool 70 in its open condition with a rolled mesh tube 73 placed over an arbor 71 and, in this case, a barbed metal insert 23 placed on top of the mesh tube on the same arbor. FIG. 18A shows an upper forming sleeve 75 coming down over arbor 71 and preparing to (a) drive the metal insert 23 into the mesh tube and (b) form the collar 15 of the wire mesh rivet 13. In this and subsequent steps, the mesh tube is supported on the bottom by stationary member 77. FIG. 18-B shows the shape of the wire mesh tube at this point in the process.

(76) FIG. 19A shows the upper forming sleeve 75 forming and compressing collar 15 from the upper portion of the mesh tube. What happens here that needs to be understood is that as the upper forming sleeve is coming down it bulges the mesh out just above spring-loaded sleeve 79. In particular, the shoulder at the top of spring-loaded sleeve 79 prevents the mesh tube from traveling downward. The more the upper sleeve goes down the more the mesh encroaches over the spring-loaded sleeve further preventing the mesh tube and, in particular the mesh shank, from traveling axially. As a result of this process, the densities of both the collar and the shank are increased, with the density of the collar being increased much more than the density of the shank. FIG. 19B shows the resulting structure.

(77) FIG. 20A shows the upper sleeve continuing even further downward, but in this case it has overcome the springs (not shown) of spring-loaded sleeve 79. As a result, the shank portion of the tube is further compressed to its final density. FIG. 20B shows the resulting finished wire mesh rivet 13 with the rivet's collar 15 having a higher density than its shank 17.

(78) It should be noted that when a metal insert having an aperture 27a which extends completely through the insert's wall is used, arbor 71 prevents the mesh from flowing into the bore of the rivet as collar 15 is formed. That is, the wire mesh enters the aperture, but is stopped from entering the rivet's bore by the arbor. Wire mesh also enters apertures 27b as the collar is formed in cases where apertures which extend only partially through the thickness of the wall of the metal insert are used.

(79) The wire mesh making up the wire mesh structure can be composed of various materials and those materials can be subjected to various treatments (including coatings) either before or after being formed into a mesh. Examples of suitable materials and treatments include, without limitation, carbon steel, stainless steel, 300 and 400 series, tin-plated carbon steel, zinc-plated carbon steel, and galvanized carbon steel. The wires making up the wire mesh can have various cross-sections, including, without limitation, round, hexagon, octagon, square, and flat. The wire mesh is preferably a knitted wire mesh, although other types of wire meshes, e.g., woven and expanded metal meshes, can be used if desired.

(80) The wire mesh rivets are preferably mounted in a dispensing strip prior to being provided to users, e.g., heat shield manufacturers. FIGS. 8 and 9 show a suitable configuration for such a dispensing strip. As can be seen in these figures, dispensing strip 31 includes a plurality of apertures 33 sized to receive the shanks 17 of rivets 13 and to allow collars 15 to be pushed through the apertures. Apertures 33 comprise a plurality of flexible fingers 35 formed by slits 37 in the body of the strip. As can be seen in FIG. 9, dispensing strip 31 can include notches 38 for use in feeding the strip to isolator forming equipment, e.g., equipment 39 of FIGS. 10 and 11 discussed below.

(81) As discussed below, the dispensing strip facilitates automation of the process which converts wire mesh rivets into wire mesh isolators. As such, the dispensing strip needs to satisfy a number of competing criteria. First, the strip needs to hold the rivets sufficiently securely so that the rivets do not become misaligned or dislodged from the strip during transport and handling. Typically, the strip will be coiled in a shipping container and dispensed directly from the container. Accordingly, the strip is preferably flexible enough to be wrapped into a coil while still minimizing misalignment and dislodgement of the rivets when coiled. Second, the rivets must be readily dispensable from the strip. In particular, the strip must have sufficient strength so that it does not buckle under the forces applied to the rivet during dispensing. Such buckling is undesirable since it can cause the strip to partially or completely lose engagement with the strip's feed mechanism. Third, the strips must be inexpensive so that they can be a disposable item.

(82) In practice, it has been found that the number and length-to-width ratio of flexible fingers 35 are important parameters in meeting these criteria for a strip composed of a low cost plastic material, such as plasticized styrene. Thus, less than 3 flexible fingers results in unacceptably high dispensing forces, as does a length-to-width ratio of less than 1:1. On the other hand, more than 16 flexible fingers results in unacceptable levels of dislodgement of the rivets from the strip, as does a length-to-width ratio greater than 3:1.

(83) Accordingly, the number of fingers 35 per aperture is preferably in the range of 3-16. As to the length-to-width ratio of the individual fingers, this parameter is preferably in the range of 1:1 to 3:1, e.g., 1.6:1. These ranges have been found to work successfully with wire mesh rivets having dimensions suitable for use in producing wire mesh isolators for vehicle heat shields, e.g., with wire mesh rivets having shank and collar OD dimensions of approximately 14 millimeters and 22 millimeters, respectively.

(84) Turning now to the process for producing wire mesh isolators from the wire mesh rivets, in broad outline, a wire mesh rivet 13 is transformed into a wire mesh isolator 11 by inserting the rivet's shank 17 in a bore in a substrate 65 (e.g., a bore 9 in a heat shield) with collar 15 engaging one side of the substrate (the proximal side of the substrate) and then compressing the portion of the shank which extends beyond the distal side of the substrate into a second collar 63 (see FIG. 16). Preferably, the proximal and distal collars 15 and 63 of the finished isolator 11 have substantially equal densities since unequal densities can cause the isolator to have compromised thermal and/or vibrational properties. The proximal and distal collars also will generally have substantially equal diameters and thicknesses, although they can be unequal if desired (see, for example, the collars of FIG. 16).

(85) In U.S. Patent Publication No. 2006/0219860 referred to above, the proximal and distal collars are formed simultaneously which requires similar forming equipment on both sides of the substrate. For some heat shield configurations (see FIG. 1), locating the forming equipment on the concave side of the heat shield is challenging because of the limited space available. The use of wire mesh rivets having a preformed collar eliminates this problem because compared to forming equipment, less bulky equipment is needed to locate the rivet in the bore and hold it in place while the collar on the opposite side of the substrate is being formed.

(86) FIGS. 10 and 11 show representative isolator forming equipment 39 which takes advantage of this aspect of the invention. The equipment includes an upper forming assembly 41 and a lower positioning assembly 43. It should be noted that the reference to the upper forming assembly and the lower positioning assembly are only for convenience of description, it being understood that the positioning assembly and the forming assembly can be reversed or can be oriented at an angle other than vertical, e.g., horizontally, if desired.

(87) FIG. 10 shows the equipment 39 in use while FIG. 11 shows the same equipment with heat shield 7 removed as well as much of the upper forming assembly 41. The limited amount of equipment needed for the lower positioning assembly 43 is evident in FIG. 11.

(88) FIG. 12 shows the lower positioning assembly 43 in more detail. As can be seen in this figure, the assembly comprises two main partsa mandrel 45 which engages the bore 21 of the rivet's wire mesh structure 19 and a sleeve 47 which includes a recess 49 which receives the rivet's preformed collar 15 and maintains the collar's shape as the wire mesh collar on the opposite side of the substrate is formed. By minimizing the difference between the outside diameter (OD) of sleeve 47 at the level of the recess and the outside diameter of preformed collar 15, the lower positioning assembly's footprint as seen from the substrate is not much larger than the footprint of the wire mesh rivet itself. In practice, the OD of sleeve 47 can be held to be within 110% of the OD of the rivet's collar, i.e., OD.sub.sleeve/OD.sub.collar1.1. Such a small footprint for the lower positioning assembly greatly facilitates the formation of wire mesh isolators for substrates having curved surfaces, such as various of the heat shields of FIG. 1.

(89) FIG. 13 shows the upper forming assembly 41 in more detail. This assembly includes a mandrel 51 which engages the bore 21 of the rivet's wire mesh structure 19 and a tamp 53 which, during use of the assembly, moves downward to the position shown in FIG. 13 to compress the wire mesh of shank 17 within the confines of sleeve 55, i.e., within the cavity 56 formed by the inner wall of sleeve 55, to form the second collar of the isolator, i.e., the collar on the upper side of the heat shield in FIG. 10. During the formation of the second collar, mandrels 45 and 51 of the lower positioning assembly and the upper forming assembly maintain an open bore along the entire length of the rivet and, as it is formed, the finished isolator. As discussed above, recess 49 in sleeve 47 of positioning assembly 43 constrains collar 15 from changing its shape as forming assembly 41 forms the second collar. As a result of these constraints applied by the mandrels and this recess, finished wire mesh isolators are produced which have well defined OD and ID dimensions and collars with substantially equal wire mesh densities.

(90) As shown in FIG. 13, forming assembly 41 preferably includes a sensor 57, e.g., a proximity switch, for detecting the position of sleeve 55. The sensor is connected to a control system (not shown) by wires 59 (see FIGS. 10 and 11). The control system allows mandrel 51 and tamp 53 to move towards the substrate only if the sensor indicates that sleeve 55 is in its most forward position, i.e., the control system only allows the mandrel and tamp to move forward if sleeve 55 is in engagement with the surface of the substrate, thus preventing an operator's hands from coming into contact with the mandrel and tamp. Sleeve 55 is itself lightly sprung so that its motion does not present a hazard to personnel operating the forming equipment. In particular, the force applied by the sleeve to the substrate is less than 10 pounds. In this way, the forming equipment avoids injury to operating personnel without the need for a light curtain or similar device to ensure that the equipment is not operated while the operator's hands are close to the equipment. If desired, more than one sensor for the position of sleeve 55 can be employed to provide redundant protection.

(91) Although not shown in FIGS. 10 and 11, a dispensing strip 31 is preferably employed to supply wire mesh rivets to isolator forming equipment 39. FIG. 14 shows such an embodiment. In particular, this figure shows positioning assembly 43 after it has removed a mesh rivet 13 from strip 31 and has moved it upward to enter the bore of a substrate (not shown). Forming assembly 41 (not shown in this figure) would then compress the shank 17 of the rivet to form second collar 63 of the finished isolator 11.

(92) FIG. 15 shows an embodiment in which multiple isolators are formed at different locations of a single substrate (e.g., a single heat shield) without the need to reposition the part. As can be seen in this figure, supporting structures 61 hold a plurality of upper forming assemblies 41 and lower positioning assemblies 43 in place relative to heat shield 7 so that isolators can be formed at each of the shield's bores. Preferably, the isolators are formed simultaneously, although sequential formation (e.g., singly or in groups) can be employed if desired. Although not shown in this figure, dispensing strips 31 are preferably used to provide wire mesh rivets to each of the lower positioning assemblies.

(93) A variety of modifications that do not depart from the scope and spirit of the invention will be evident to persons of ordinary skill in the art from the foregoing disclosure. For example, although the invention has been illustrated in terms of heat shields employed in vehicle exhaust systems, it can be used in a variety of other applications where thermal and/or acoustical isolation is desired. Similarly, the invention is not limited to the particular types of heat shields illustrated herein but can be used with other heat shields now known or subsequently developed. Also, the invention can be used with single layer metal substrates or more complex substrates having multiple metal layers or a combination of metal and non-metallic layers, e.g., layers of ceramic or glass fibers. The following claims are intended to cover these and other modifications, variations, and equivalents of the embodiments disclosed herein.