Typical absorption type silencers or mufflers 10 shown in
Another type of silencer is what is typically called a reflective silencer. In reflective silencers, elements are designed to reflect or generate sound waves that destructively interfere with sound waves emanating from the engine. One type of acoustic reflective element is commonly known as a Helmholtz resonator. A Helmholtz resonator is a chamber with an open throat. A volume of air located in the chamber and throat vibrates because of periodic compression of the air in the chamber. Helmholtz resonators may be attached to exhaust pipes of internal combustion engines as is shown in
Typically, the peak attenuation frequency of sound energy, i.e., the frequency at which the greatest transmission loss occurs, is a function of the volume of the chamber portion 54b of the Helmholtz resonator 54 and the throat portion inner diameter DT and length LT. For example, if the chamber volume increases and the throat portion inner diameter DT, and length LT remain the same, the peak attenuation frequency decreases, and if the chamber volume decreases, the peak attenuation frequency increases.
When the Helmholtz resonator 54 is attached as a side branch, as shown in
The transmitted power is zero when w=w0 in Eq. (1), which is the resonance frequency of the resonator, at which all of the energy is reflected back towards the source. These filters decrease sound within a band around the resonance frequency, and pass all other frequencies. The narrow frequency range over which interference occurs is normally not a desired condition in an automobile exhaust since the frequency of the acoustic energy will vary as the engine speed (RPM) varies and as the temperature of the exhaust gases vary.
The invention relates to an exhaust silencer or muffler for an internal combustion engine, in particular, a silencer, with the damping characteristics of a Helmholtz resonator and the absorptive characteristics of a dissipative silencer for an internal combustion engine. It is an object of the present invention to provide an improved silencer or muffler for use with an internal combustion engine that incorporates one or more both a dissipative silencer elements and one or more reflective elements such as a Helmholtz resonator. It is another object of the invention to provide improved dissipative element and resonators for use in such a muffler It is a further object of the invention to provide a combined dissipative silencer and resonator in a single muffler assembly suitable for use with standard automotive construction techniques which has superior performance compared to prior art.
The muffler 10 of
Provided within the outer shell 12 and positioned between the pipe 14 and the shell 12 is a fibrous material 18. The fibrous material 18 substantially fills both the first and second chambers 13b and 13c. The fibrous material 18 may be formed from one or more continuous glass filament strands, wherein each strand comprises a plurality of filaments which are separated or texturized via pressurized air so as to form a loose wool-type product in the outer shell 12, see, e.g., U.S. Pat. Nos. 5,976,453 and 4,569,471, the disclosures of which are incorporated herein by reference in their entireties. The filaments may be formed from continuous glass strands, such as, for example, E-glass, S2-glass, or other glass compositions. The continuous strand material may comprise an E-glass roving such as a low boron, low fluorine, high temperature glass sold by Owens Corning under the trademark ADVANTEX® or an S2-glass roving sold by Owens Corning under the trademark ZenTron®.
It is also contemplated that a ceramic fiber material may be used instead of a glass fibrous material to fill the outer shell 12. Ceramic fibers may used to fill directly into the shell or used to form a muffler preform, which is subsequently placed in the shell 12. It is also contemplated that preforms may be made from a discontinuous glass fiber product produced via a rock wool process or a spinner process, such as one of the spinner processes used to make fiber glass thermal insulation for residential and commercial applications, or from glass mat products.
It is additionally contemplated that continuous glass strands can be texturized and formed into one or more preforms, which may then be placed in the shell parts 12a or 12b prior to coupling the shell parts 12a and 12b to form the preform. Processes and apparatus for forming such preforms are disclosed in U.S. Pat. Nos. 5,766,541 and 5,976,453, the disclosures of which are incorporated herein by reference in their entireties. Fibrous material 18 may contain loose discontinuous glass fibers, e.g., E glass fibers, or ceramic fibers which are manually or mechanically inserted into the shell 12.
It is also contemplated that the fibrous material 18 may be filled into bags made from plastic sheets or glass or organic material mesh and subsequently placed into the shell parts 12a and 12b, see, e.g., U.S. Pat. No. 6,068,082, and formerly co-pending application, U.S. patent application Ser. No. 09/952,004, now U.S. Pat. No. 6,607,052, the disclosures of which are incorporated herein by reference in their entireties. It is additionally contemplated that the fibrous material 18 may be inserted into the outer shell 12 via any one of the processes disclosed in: U.S. Pat. Nos. 6,446,750; 6,412,596; and 6,581,723 the disclosures of which are incorporated herein by reference in their entireties.
It is further contemplated that the one or more continuous glass filament strands may be fed into openings (not shown) in the outer shell 12 after the shell parts 12a and 12b have been coupled together along with pressurized air such that the fibers separate from one another and expand within the outer shell 12 and form a “fluffed-up” or wool-type product within the outer shell 12. Processes and apparatuses for texturizing glass strand material which is fed into a muffler shell are described in U.S. Pat. Nos. 4,569,471 and 5,976,453, the disclosures of which are incorporated herein by reference by reference in their entireties. It is further contemplated that the fibrous material 18 may be inserted into the muffler in the form of mats of continuous or discontinuous fibers. Needled felt mats of discontinuous glass fibers may be inserted in the muffler as a preform or are rolled into a perforated tube which is then inserted into the muffler.
Acoustic energy passes through the perforated pipe 14 to the fibrous material 18 which functions to dissipate the acoustic energy. The fibrous material 18 also functions to thermally protect or insulate the outer shell 12 from energy in the form of heat transferred from high temperature exhaust gases passing through the pipe 14.
As noted above, the transmission loss of a silencer or muffler 10 filled with absorptive material 18 can be enhanced at certain frequency ranges by placing a baffle or plate 15 in the silencer inner chamber 13a so as to separate the silencer inner chamber 13a into two absorptive chambers 13b and 13c. Modeled transmission loss (dB) data is illustrated in
Transmission loss is a measure in dB of the amount of sound energy that is attenuated as a sound wave passes through a muffler. In other words, transmission loss, at a given frequency, is equal to a sound level (dB) at the given frequency where no attenuation has occurred via a silencer or otherwise minus a sound level (dB) at that same frequency where some attenuation has occurred, such as by a silencer. As shown in
Actual measured transmission loss (dB) data is illustrated in
As is apparent from
The muffler 50 includes a Helmholtz resonator 54 comprising a throat portion 54a having an inner diameter DT and a length LT, and a chamber portion 54b having an inner diameter DC and a length LC.
Typically, the peak attenuation frequency of sound energy, i.e., the frequency at which the greatest transmission loss occurs, is a function of the volume of the chamber portion 54b of the Helmholtz resonator 54 and the throat portion inner diameter DT, and length LT. For example, if the chamber volume increases and the throat portion inner diameter DT, and length LT remain the same, the peak attenuation frequency decreases, and if the chamber volume decreases, the peak attenuation frequency increases.
The peak attenuation frequency is lowered without increasing the volume of the chamber portion 54b by lining one or more inner walls of the chamber portion 54b with an acoustically absorbing material 70. In the embodiment illustrated in
The fibrous material 70a may be formed from one or more continuous glass filament strands, wherein each strand comprises a plurality of filaments which are separated or texturized via pressurized air so as to form a loose wool-type product, see U.S. Pat. Nos. 5,976,453 and 4,569,471, the disclosures of which are incorporated herein by reference. The filaments may be formed from, for example, E-glass or S2-glass, or other glass compositions. The continuous strand material may comprise an E-glass roving sold by Owens Corning under the trademark ADVANTEX® or an S2-glass roving sold by Owens Corning under the trademark ZenTron®.
It is also contemplated that continuous or discontinuous ceramic fiber material may be used instead of glass fibrous material to line the walls 55a-55b of the chamber portion 54b. The fibrous material 70a may also comprise loose discontinuous glass fibers, e.g., E glass fibers, or ceramic fibers, or a discontinuous glass fiber product produced via a rock wool process or a spinner process similar to those used to make fiber glass thermal insulation for residential and commercial applications, or a glass mat.
When the Helmholtz resonator 54 is attached as a side branch, as shown in
As shown in
During the second test, where the first and second walls 55a-55b were lined with approximately 1 inch of fibrous material 70a at a fill density of about 100 grams/liter, peak frequency attenuation occurred at about 90 Hz. The transmission loss at 90 Hz was approximately 30 dB. The half-height frequency attenuation points on the second test curve were at frequencies of 75 Hz and 108 Hz. The transmission loss at 75 Hz and 108 Hz was approximately 15 dB.
During the third test, where the first and second walls 55a-55b were lined with approximately 2 inches of fibrous material 70a at a fill density of about 100 grams/liter, peak frequency attenuation occurred at about 81 Hz. The transmission loss at 81 Hz was approximately 22 dB. The half-height frequency attenuation points on the third test curve were at frequencies of 58 Hz and 117 Hz. The transmission loss at 58 Hz and 117 Hz was approximately 11 dB.
During the fourth test, where the entire chamber portion 54b was filled with fibrous material 70a at a fill density of about 100 grams/liter, peak frequency attenuation occurred at about 74 Hz. The transmission loss at 74 Hz was approximately 12 dB. The transmission loss curve was substantially flat in shape.
During the fifth test, where the first and second walls 55a-55b were lined with approximately 1 inch of fibrous material 70a at a fill density of about 63 grams/liter, peak frequency attenuation occurred at about 91 Hz. The transmission loss at 91 Hz was approximately 30 dB. The half-height frequency attenuation points on the second test curve were at frequencies of 75 Hz and 113 Hz. The transmission loss at 75 Hz and 113 Hz was approximately 15 dB.
With regard to each of tests 2, 3 and 5, where the walls 55a-55b of the chamber portion 54b were lined with fibrous material 70a, the frequency at which peak sound energy absorption occurred was lowered and the range of frequencies at which a transmission loss equal to approximately half that occurring at the peak attenuation frequency was broadened. Therefore, by lining the walls 55a-55b of the chamber portion 54b with fibrous material 70a, a broader half-height attenuation range (i.e., a range of frequencies between end points falling on the transmission loss curve where a transmission loss occurred equal to approximately one-half of that occurring at the peak attenuation frequency) was provided. It was noted that the peak absorption or attenuation frequency typically shifted with temperature changes. It was also noted that the peak noise frequency to be attenuated typically shifted with engine RPM. Thus, a muffler or silencer having a narrow half-height attenuation range may be found to be unacceptable as the peak noise frequency may move outside of the attenuation range during operation of the vehicle, i.e., as the engine speed varies. Because a broader half-height attenuation range is provided by an aspect of the present invention, it is more likely that the attenuation effected by the muffler 50 will be found to be acceptable during operation of a vehicle, i.e., as the motor speed varies and secondarily as the muffler temperature varies. Further with regard to tests 2, 3 and 5, it was noted that the frequency of peak attenuation was reduced without increasing the dimensions of the chamber portion 54b or throat portion 54a.
It was also noted that by lining the walls 55a-55b of the chamber portion 54b with fibrous material 70a, heat transfer to the walls 55a-55b was reduced, thereby allowing the muffler outer shell 52 to stay cooler. Consequently, the outer shell 52 may be formed from a material having a lower heat resistance threshold, such as a composite material.
The silencer 500 comprises a rigid outer shell 502 formed from a metal, a resin or a composite material comprising, for example, reinforcement fibers and a resin material. Example outer shell composite materials are set out in the '972 patent. The outer shell 502, in the illustrated embodiment, preferably has a substantially oval shape. The outer shell 502 may have any other geometric shape so long as the requisite volumes for the dissipative silencer component 510 and the Helmholtz resonator component 520 to effect the desired attenuation are retained.
A pipe, typically with no abrupt bends, such as the substantially straight pipe 600 illustrated in
A first portion 602 of the pipe 600, which is not perforated, extends through a cavity 522 of the Helmholtz resonator component 520. A second portion 604 of the pipe 600 is perforated and forms part of the dissipative silencer component 510. A third portion 606 of the pipe 600 is also perforated and forms part of the connection component 530, which, as noted above, joins the dissipative component 510 with the reactive component 520. The second portion 604 of the pipe 600 is perforated so as to have a porosity, i.e., a percentage of open area to closed area, of between about 5% to about 60%. The third portion 606 of the pipe 600 is perforated so as to have a porosity of between about 20% to about 100%.
In the illustrated embodiment, the dissipative silencer component 510 comprises a substantially oval cavity 510a having a length L2, a height L5 and a width L4, see
The dissipative silencer component 510 further comprises fibrous material 512a. The fibrous material 512a may be formed from one or more continuous glass filament strands, wherein each strand comprises a plurality of filaments which are separated or texturized via pressurized air so as to form a loose wool-type product, see U.S. Pat. Nos. 5,976,453 and 4,569,471, the disclosures of which are incorporated herein by reference. The filaments may be formed from, for example, E-glass or S2-glass, or other glass compositions. The continuous strand material may comprise an E-glass roving sold by Owens Corning under the trademark ADVANTEX® or an S2-glass roving sold by Owens Corning under the trademark ZenTron®.
It is also contemplated that continuous or discontinuous ceramic fiber material may be used instead of glass fibrous material for filling the cavity 510a. The fibrous material 512a may also comprise loose discontinuous glass fibers, e.g., E glass fibers, or ceramic fibers, a discontinuous glass fiber product produced via a rock wool process or a spinner process similar to those used to make fiber glass thermal insulation for residential and commercial applications, or a glass mat.
End plates 514a and 514b, each having a first opening 514c with a diameter D2 and a second opening 514d with a diameter D1 are provided for retaining the fibrous material 512a in the cavity 510a. The end plates 514a and 514b are coupled to the outer shell 502 and are oval in shape. The end plates 514a and 514b may have one or more additional holes to facilitate filling of the cavity 510a with fibrous material.
The Helmholtz resonator component 520 comprises the cavity portion 522 and the neck portion 524a. The cavity portion 522 has a substantially oval shape in cross section, a length L1, a height L5 and a width L4, see
The connection component 530 comprises a substantially oval cavity 530a having a length L3, a height L5 and a width L4, see
The silencer 700 comprises a rigid outer shell 702 formed from a metal, a resin or a composite material comprising, for example, reinforcement fibers and a resin material. Examples of outer shell composite materials are set out in the '972 patent. The outer shell 702, in the illustrated embodiment, has a substantially cylindrical shape. The outer shell 702 may have any other geometric shape so long as the requisite volumes for the dissipative silencer component 710 and the Helmholtz resonator component 720 to effect the desired attenuation are retained.
A substantially straight pipe 800 is coupled to the outer shell 702 and extends through the entire length of the outer shell 702. Conventional exhaust pipes, not shown, may be coupled to outer ends of the pipe 800. Because the pipe 800 is formed without abrupt bends, back pressure and flow losses through the silencer 700 are reduced.
A first portion 802 of the pipe 800, which is substantially solid and not perforated, extends through a cavity 722 of the Helmholtz resonator component 720. A second portion 804 of the pipe 800 is perforated and forms part of the dissipative silencer component 710. A third portion 806 of the pipe 800 is also perforated and forms part of the connection component 730, which, as noted above, joins the dissipative component 710 with the reactive component 720. The second portion 804 of the pipe 800 is perforated so as to have a porosity of between about 5% to about 60%. The third portion 806 of the pipe 800 is perforated so as to have a porosity of between about 20% to about 100%.
In the illustrated embodiment, the dissipative silencer component 710 comprises a substantially cylindrical cavity 710a defined between an inner, substantially straight, non-perforated pipe 711 and the pipe 800. The cavity 710a has an outer diameter D3, an inner diameter D1 and a length L2, see
End plates 714a and 714b, each having a first opening 714c with a diameter D1 are provided for retaining the fibrous material 512a in the cavity 710a. The end plates 714a and 714b may be welded or otherwise coupled to the pipe 800. Further, support elements (not shown) may extend from the plates 714a and 714b and be coupled to the outer shell 702. The end plates 714a and 714b may have one or more additional holes to facilitate filling of cavity 710a with fibrous material.
The Helmholtz resonator component 720 comprises the cavity portion 722 and a neck portion 724a. The cavity 722 has a substantially cylindrical shape in cross section, a length L1 an outer diameter D2 and an inner diameter D1. Passing through the cavity portion 722, and not forming part of the Helmholtz resonator component 720 is the pipe portion 802. The neck portion 724a defines a hollow, ring-shaped cavity 724b having a length L2, an outer diameter D2 and an inner diameter D3, see
The connection component 730 comprises a substantially cylindrical cavity 730a having a length L3, an outer diameter D2 and an inner diameter D1, see
For a simple dissipative silencer component geometry, such as the cylindrical cavity 710a illustrated in
where ρ0 and k denote, respectively, the density and the wave number in air, and ρ0/1 and k0/1 the complex dynamic density and the wave number in the absorptive material, ζp0/0 the nondimensionalized acoustic impedance of perforation. In view of the decoupling approach and rigid boundary conditions (u=0) at the wall of the cylindrical cavity 710a, the acoustic pressure (p) and particle velocity (u) at the inlet (x=0) and outlet (x=L2) of the dissipative silencer component pipe portion 804 may be related by the following equation (4):
which defines the transfer matrix elements, Tij(c0=speed of sound). For a pipe portion 804 with a constant cross-sectional area, transmission loss can then be calculated from the transfer matrix as follows:
The perforate impedance ζp0/0 relates the acoustic pressures in the pipe portion 804 and the cylindrical cavity 710a at the interface. Semi-empirical acoustic impedance of perforation facing absorptive fibrous material 512a can be expressed in terms of the hole geometry and acoustic properties of the absorptive fibrous material 512a as
where tw is the thickness of the wall of the pipe portion 804, dh the perforation hole diameter, φ the porosity of the pipe portion 804, C1 and C2 are coefficients determined experimentally. The acoustic properties of absorptive material can also be obtained experimentally and expressed as a function of frequency (f) and flow resistivity (R),
where coefficients C3−C6 and exponents n1−n4 are dependent on the properties of the absorptive fibrous material 512a. Details of this analysis are set forth in the publication: A. Selamet, I. J. Lee, Z. L. Ji, and N. T. Huff, “Acoustic attenuation performance of perforated absorbing silencers,” SAE Noise and Vibration Conference and Exposition, April 30-May 3, SAE Paper No. 2001-01-1435, Traverse City, Mich., which is incorporated herein by reference in its entirety (“SAE Paper No. 2001-01-1435”).
The Helmholtz resonator components 520 and 720 are effective acoustic attenuation devices at low frequencies. Each has a resonance, i.e., peak attenuation frequency, dictated by the combination of its cavity portion 522, 722 and neck portion 524a, 724a, their dimensions and relative orientations. The resonance frequency may be approximated by the classical lumped analysis given by:
where c0 is the speed of sound, An the neck portion cross-sectional area, Vc the cavity portion volume, In the neck portion length, see
A silencer was constructed as shown in
Test apparatus (not shown) was provided comprising a source of sound energy, an input pipe coupled to an inlet of the pipe 600 and an output pipe coupled to the outlet of the pipe 600. Microphones were provided at the input and output pipes for sensing sound pressure levels at those locations for frequencies from about 20 Hz to about 3200 Hz. Sound transmission losses at each frequency were determined from the signals generated by those microphones. Experiments were performed with all elements at ambient temperatures.
During a first test run, the input and output pipes were two inches in diameter, approximately equal to the diameter of the pipe 600. During a second test run, the input and output pipes were three inches in diameter. Three-inch-to-two-inch transition sections were provided between the input and output pipes and the inlet and outlet ends of the pipe 600.
Also illustrated in
As is apparent from
A silencer was constructed as shown in
Test apparatus (not shown) was provided which included a source of sound energy, an input pipe coupled to an inlet of the pipe 600 and an output pipe coupled to the outlet of the pipe 600. Microphones were provided at the input and output pipes for sensing sound pressure levels at those locations for frequencies from about 20 Hz to about 3200 Hz. Sound transmission losses at each frequency were determined from the outputs of those microphones. Experiments were performed with all test elements at ambient temperature.
During the test runs designated “Prototype OSU” and “Prototype OC” in
Also illustrated in
As is apparent from
The silencer 900 comprises a rigid outer shell 902 formed from a metal, a resin, or a composite material comprising, for example, reinforcement fibers and a resin material. Examples of outer shell composite materials are described in the '972 patent. The outer shell 902, in the illustrated embodiment, has a substantially cylindrical shape. However, the outer shell 902 may have any other geometric shape so long as the requisite volumes for the dissipative silencer components 910a and 910b and the Helmholtz resonator component 920 to effect the desired attenuation are retained.
Perforated first and second pipes 980a and 980b, each formed without abrupt bends, are coupled to the outer shell 902 and typically extend part way through the outer shell 902, such that a gap 982 is provided within the shell 902 between the two pipes 980a and 980b, see
In the illustrated embodiment, the dissipative silencer components 910a and 910b each comprise a substantially cylindrical cavity 912a, 912b defined between an inner, substantially straight, non-perforated pipe 914a, 914b and one of the pipes 980a and 980b. Support brackets (not shown) may extend from the pipes 914a, 914b and be coupled to the outer shell 902. Cavity 912a has an outer diameter D2, an inner diameter D1 and a length L1 while cavity 912b has an outer diameter D2, an inner diameter D1 and a length L3. Each dissipative silencer component 910a, 910b may be filled with fibrous material 512a, such as described above with regard to the embodiment illustrated in
Disk-shaped end plates 925a and 925b, each having a first opening 925c with a diameter D1 are provided for retaining the fibrous material 512a in the cavities 912a and 912b. The end plates 925a and 925b may be welded or otherwise coupled to the pipes 980a, 980b, 914a, 914b.
The Helmholtz resonator component 920 comprises a cavity portion 922 and a neck portion 924 defined by the gap 982. The cavity 922 has a cylindrical shape in cross section, a length=L1+L2+L3 an outer diameter D3 and an inner diameter D2. The neck portion 924 defines a disk-shape opening having an inner diameter D1, an outer diameter D4 and a length L2. The neck portion 924 is defined by the end plates 925a and 925b. The neck portion 924 may alternatively have other geometric shapes, such as cones, cylinders and square tubes. Lengthening the neck portion 924 by an extension into the cavity portion 922 helps attain lower resonance frequencies, see equation 7 above. Shortening the length L2 between the dissipative silencer components 910a and 910b may also help achieve a higher transmission loss at lower frequencies. The effect of geometry including the neck portion location can be accurately predicted by Boundary Element Method.
The silencer 1000 comprises a rigid outer shell 1002 formed from a metal, a resin, or a composite material comprising, for example, reinforcement fibers and a resin material. Example outer shell composite materials are set out in the '972 patent. The outer shell 1002, in the illustrated embodiment, has a substantially oval shape. The outer shell 1002 may have any other geometric shape so long as the requisite volumes for the dissipative silencer component 1010 and the Helmholtz resonator component 1020 to effect the desired attenuation are retained.
Pipes, such as substantially straight pipes 1060, 1064, are coupled to the rigid outer shell 1002 and extend through the entire length of the outer shell 1002. The pipe may include pipes having a slight bend or angle, an S-shaped pipe, etc. Conventional exhaust pipes, not shown, may be coupled to outer ends of the pipes 1060, 1064. The pipe 1064 is preferably spaced a sufficient distance away from the inner wall 1002a of the outer shell 1002 so as to allow a sufficient amount of fibrous material 1012 to be provided between the pipe 1064 and the shell inner wall 1002a to allow for adequate thermal insulation of the outer shell 1002 and to prevent interference by the outer shell 1002 with acoustic attenuation by the dissipative component 1010.
A portion 1062 of pipe 1060, which is not perforated, extends through a cavity 1022 of the Helmholtz resonator component 1020. Pipe 1064 is perforated and forms part of the dissipative silencer component 1010. Between pipe 1060 and 1064 is connection component 1030, which joins dissipative component 1010 and reactive component 1020 with pipe 1062. Pipe 1064 is typically perforated so as to have a porosity, i.e., a percentage of open area to closed area, of between about 5% to about 60%.
The cavity 1022 of the Helmholtz resonator may optionally include a fibrous material 1070 such as glass, mineral or metallic fibers that improve the acoustical properties thereof. Accordingly the silencers of the present invention include a dissipative silencer exhibiting a desirable broadband noise attenuation at frequencies above about 150 Hz at ambient temperature and a resonator component exhibiting desirable noise attenuation at low frequencies, e.g., from about 50 to about 120 Hz at ambient temperature, to form an effective attenuator over a wide range of frequencies.
One skilled in the art will appreciate that the description and drawings form broad teachings which may be implemented in a variety of forms. This invention has been described with reference to particular examples and drawing figures. However the true scope of the invention should not be limited to particular examples and drawing figures since modifications and alterations will be apparent to those in the art after a review of the drawings, specification and claims.
Number | Name | Date | Kind |
---|---|---|---|
1878424 | Oldberg | Sep 1932 | A |
2014666 | Peik | Sep 1935 | A |
2051515 | Bourne | Aug 1936 | A |
2059487 | Peik | Nov 1936 | A |
2075263 | Bourne | Mar 1937 | A |
2139151 | Deremer | Dec 1938 | A |
2166408 | Hoyle | Jul 1939 | A |
2326612 | Bourne | Aug 1943 | A |
2501306 | Bessiere | Mar 1950 | A |
2523260 | Campbell | Sep 1950 | A |
2937707 | Ernst | May 1960 | A |
3180712 | Hamblin | Apr 1965 | A |
3434565 | Fischer | Mar 1969 | A |
3710891 | Flugger | Jan 1973 | A |
3738448 | Ver et al. | Jun 1973 | A |
3754619 | McCormick | Aug 1973 | A |
4046219 | Shaikh | Sep 1977 | A |
4278147 | Watanabe et al. | Jul 1981 | A |
4342373 | Erickson et al. | Aug 1982 | A |
4501341 | Jones | Feb 1985 | A |
4513841 | Shimoji et al. | Apr 1985 | A |
4523662 | Tanaka et al. | Jun 1985 | A |
4569471 | Ingemansson et al. | Feb 1986 | A |
4700805 | Tanaka et al. | Oct 1987 | A |
4834214 | Feuling | May 1989 | A |
4841728 | Jean et al. | Jun 1989 | A |
4846302 | Hetherington | Jul 1989 | A |
5198625 | Borla | Mar 1993 | A |
5350888 | Sager, Jr. et al. | Sep 1994 | A |
5365025 | Kraai et al. | Nov 1994 | A |
5602368 | Kaneso | Feb 1997 | A |
5659158 | Browning et al. | Aug 1997 | A |
5766541 | Knutsson et al. | Jun 1998 | A |
5773770 | Jones | Jun 1998 | A |
5783780 | Watanabe et al. | Jul 1998 | A |
5783782 | Sterrett et al. | Jul 1998 | A |
5976453 | Nilsson et al. | Nov 1999 | A |
6068082 | D'Amico et al. | May 2000 | A |
6089348 | Bokor | Jul 2000 | A |
6354398 | Angelo et al. | Mar 2002 | B1 |
6386317 | Morohoshi et al. | May 2002 | B1 |
6412596 | Brandt et al. | Jul 2002 | B1 |
6415888 | An et al. | Jul 2002 | B2 |
6446750 | Lewin | Sep 2002 | B1 |
6581723 | Brandt et al. | Jun 2003 | B2 |
6607052 | Brandt et al. | Aug 2003 | B2 |
6668972 | Huff et al. | Dec 2003 | B2 |
20010015301 | Kesselring | Aug 2001 | A1 |
20020121404 | Storm | Sep 2002 | A1 |
20020144860 | Galaitsis | Oct 2002 | A1 |
Number | Date | Country |
---|---|---|
10132164 | Jan 2002 | DE |
589516 | Mar 1994 | EP |
403651 | Dec 1938 | GB |
56014820 | Feb 1981 | JP |
59041618 | Mar 1984 | JP |
01190912 | Aug 1989 | JP |
02112608 | Apr 1990 | JP |
05232967 | Sep 1993 | JP |
05240120 | Sep 1993 | JP |
06280542 | Oct 1994 | JP |
10252442 | Sep 1998 | JP |
Number | Date | Country | |
---|---|---|---|
20040262077 A1 | Dec 2004 | US |
Number | Date | Country | |
---|---|---|---|
60467468 | May 2003 | US |