The various features and advantages of this invention will become apparent to those skilled in the art from the following detailed description of the currently preferred embodiment. The drawings that accompany the detailed description can be briefly described as follows.
In one example, the engine 22 produces pressure pulses, or acoustic waves, associated with combustion cycles of firing one or more pistons. Noise is caused by the release of the pressure pulses. The valve 42 of the noise attenuation device 28 reduces the noise by reflection. The acoustic waves are reflected back and forth within the exhaust system 20. At each reflection, the sound waves lose energy. As result, only a fraction of the noise leaves the exhaust system 20.
Referring to an isolated view of the valve 42 in
The bias member 54 includes a first extended portion 56a that abuts a first arm 58a that extends from the frame 48. A second extended portion 56b extends from the other end of the bias member 54 and abuts a second arm 58b that extends from a fastener 60 that is received onto the threaded member 52.
In the illustrated example, the valve plate 44 extends into the exhaust tube section 40 (
Referring to
The first section 70a includes a slot 72 for mounting the valve 42. The slot 72 is near a transition section 74 between the first section 70a and the second section 70b. The slot 72 includes notches 76 at each corner of the slot 72 for receiving corresponding portions of the frame 48. In this example, the frame 48 fits within the notches 76 to secure the valve 42 in place. Optionally, the frame 48 is welded or secured in another known manner to the exhaust tube section 40 to lock the valve 42 in place. Alternatively, the valve 42 is mounted to walls of the exhaust tube section 40 in a known manner without the slot 72. In one example, the valve 42 is mounted within the first section 70a of the exhaust tube section 40 before the first section 70a is secured to the second section 70b. In another example, the first section 70a is formed, such as by stamping, with a suitable mounting portion for attaching the valve 42. Given this description, one of ordinary skill in the art will recognize other suitable designs for mounting the valve 42.
In this disclosed example, the bias member 54 biases the valve plate 44 toward a predetermined, minimum flow position, such as the position shown in
The bias member 54 is located outside of the exhaust tube section 40. In this example, the bias member 54 is within a heat transfer environment H that removes heat to maintain the bias member 54 below a threshold temperature. For example, the exhaust gas conveyed through the exhaust tube section 40 is approximately 1000° C. A portion of the heat from the exhaust gas is transferred through the valve plate 44 to the bias member 54. In this example, the heat transfer environment H provides a surrounding ambient airflow that removes and transfers the heat away to maintain the bias member 54 at a lower temperature than the exhaust gas. In one example, the lower temperature permits the bias member 54 to be made from standard types of materials rather than expensive, specialized materials for withstanding elevated temperatures. In one example, the heat transfer environment H is a relatively uncontained volume around the exhaust tube section 40, such as an ambient airflow adjacent an undercarriage of a vehicle.
Operationally, the valve 42 functions as a passive throttle within the exhaust tube 24 to attenuate acoustic waves carried by the exhaust gases. The valve plate 44 reflects a portion of the acoustic waves to attenuate noise as described above. The valve plate 44 pivots with the pivot shaft 46 about an axis A in response to a force exerted on a valve plate 44 from the flow of the exhaust gas. The valve plate 44 pivots between the minimum flow position and a maximum flow position (
Rotation of the pivot shaft 46 causes the threaded member 52 and fastener 60 to also rotate. Rotation of the fastener 60 moves the second arm 58b against the second extended portion 56b of the bias member 54. The first extended portion 56a of the bias member 54 presses against the first arm 58a and provides resistance to rotation. Thus, movement of the valve plate 44 acts against the biasing force provided by the bias member 54.
The flow of exhaust gases tends to move the valve plate 44 from the minimum flow position shown in
Operationally, the first link 88a pivots with movement of the valve plate 44′ due to the force of the exhaust gas. Movement of the first link 88a moves the third link 88c, which in turn rotates the second link 88b against the bias force of the bias member 54′.
In this example, the bias member 54′ includes a spring having a spring constant associated with the amount of force necessary to compress the bias member 54′ a given amount. In the position shown in
The amount of force and the spring constant can be determined in a known manner at various rotational positions of the valve plate 44′ and depends on the length of the links 88a, 88b, and 88c, angles between the links 88a, 88b, and 88c, angular velocity, angular acceleration, and inertia of a given example. As a result of the varying amount of force required to pivot the valve plate 44′, the spring constant is effectively changed over the rotation of the valve plate 44′. Varying the effective spring constant provides the benefit of tailoring the response of the valve 42 in a desired manner over the rotational position of the valve plate 44′ based upon an expected exhaust gas flow.
Although a preferred embodiment of this invention has been disclosed, a worker of ordinary skill in this art would recognize that certain modifications would come within the scope of this invention. For that reason, the following claims should be studied to determine the true scope and content of this invention.