The present invention relates to exhaust gas recirculation (EGR) valves for internal combustion engines; more particularly, to EGR valves having a poppet valve stem actuated by a rotary cam; and most particularly, to such an EGR valve wherein the valve seating force between the valve head and the valve seat is attenuated by a mechanical shock-absorbing mechanism disposed between the valve stem and the valve head.
Recirculation of exhaust gas into the air intake stream of an internal combustion engine is well known, both for spark-ignited (SI) engines and for compression-ignited (CI) engines. Such recirculation requires a rugged, dependable, precision valve, typically a poppet valve, disposed in a cross-over between an engine's exhaust system and intake system. In many prior art automotive uses, an EGR poppet valve is actuated by a linear solenoid attached to the valve stem. However, a rotary cam driven by an electric motor is also a well known actuation means, especially for diesel-powered automotive applications in Europe. Such usage is expected to become more prevalent world wide.
For ease of presentation, the terms “rotary cam” and “rotary EGR valve” as employed herebelow should be taken to mean any arrangement wherein the linear action of the valve stem is controlled by the rotary motion of an eccentric coupled in some fashion to the valve stem.
Rotary EGR valves have become especially popular because of the generally high force margins they enjoy over other designs, and particularly because of inherent significant mechanical advantages through gearing and camming. Typically, this genre of valves is actuated in both opening and closing directions, as well as in parked (closed) position during engine operation when EGR flow may not be desired.
A disadvantage of such actuation is inherently high and sustained forces imposed on the valve actuation train that can prove detrimental for long-term wear, including grooving of the valve head, wear of the valve seat, and degradation of the interface between the cam and its roller follower on the valve stem. Such wear can result in high break-loose forces and “kinking”, leading to poor controllability in the just off-parked position.
Of course, these considerations pertain not only to rotary EGR valves but also to all poppet valves actuated by powerful actuators, whether rotary cams or linear solenoids.
What is required is a means for attenuating the seating force of a poppet valve without compromising the timing or the closing reliability of the valve.
It is a principal object of the present invention to attenuate the seating force of a poppet valve.
Briefly described, means for attenuating the seating force of a poppet valve comprises a shock-absorbing member disposed in the poppet between the valve stem and valve head. In a currently preferred embodiment, the shock-absorbing member is a wave washer disposed around the valve stem and captured between the valve stem and the valve head, between which axial motion is allowed. After the valve head engages the valve seat to close the valve, any further travel of the actuator is absorbed by compression of the wave washer, thus attenuating additional force on elements of the valve actuation train. In opening the valve, the reverse occurs in that initial motion of the actuator serves to relieve compression of the wave washer, followed then by removal of the valve head from the valve seat.
The present invention will now be described, by way of example, with reference to the accompanying drawings, in which:
Corresponding reference characters indicate corresponding parts throughout the several views. The exemplifications set out herein illustrate two currently-preferred embodiments of the invention, and such exemplifications are not to be construed as limiting the scope of the invention in any manner.
Referring to
It will be observed that slot side 50 drives roller 32 in valve-opening mode and slot side 52 drives roller 32 in valve-closing mode. Motor 54 may be de-energized at any point in the rotary travel of cam plate 42, locking the valve stem at that position.
As described above, when the cam plate is driven to the valve-closed position, from the moment that the valve head mates with the valve seat, compressive force of the head against the seat and tensile force between the head and the roller and slot side 52 can become extremely large, and ultimately damaging, with continued rotation of the cam plate because the valve actuation train is mechanically unyielding.
Referring to
A valve body 112 defines a first chamber 114 and a second chamber 116 separated by a valve seat 118. First chamber 114 may be in communication with an exhaust system 115 of an internal combustion engine 113, and second chamber 116 may be in communication with an intake system 117 of engine 113, or the reverse. A bore 120 in a wall of second chamber 116 is concentric with valve seat 118 and retains a bushing/seal 122 and a valve stem 124 of a poppet valve 125 slidably disposed in bushing/seal 122. Stem 124 extends through second chamber 116 and slidably engages at a first end 126 within body 112 a valve head 128 for variably mating with valve seat 118 to variably open and close valve assembly 100 between chambers 114,116 in response to axial motion of stem 124.
At a first surface 160 of valve head 128, stem 124 is stepped to provide a load surface 162 on surface 160 for opening the valve. A recess 164 is provided in second surface 166 for receiving a shock absorbing member, provided exemplarily in
Referring now to
A valve body 212 defines a first chamber 214 and a second chamber 216 separated by a valve seat 218. A bore 220 in a wall of second chamber 216 is concentric with valve seat 218 and retains a bushing/seal 222 and a valve stem 224 of poppet valve 225 slidably disposed in bushing/seal 222. Stem 224 extends through second chamber 216 and engages at a first end 226 within body 212 a valve head 228 for variably mating with valve seat 218 to variably open and close valve assembly 200 between chambers 214,216 in response to axial motion of stem 224.
A recess 264 is provided in first valve head surface 260 for receiving a shock absorber, provided exemplarily in
Second embodiment 200 is advantageous over first embodiment 100 in not having a potential leak path through the valve head past the valve stem; in embodiment 100, a close tolerance is required between the valve stem and the head bore to prevent leakage. However, a disadvantage of second embodiment 200 is that an additional component, second force plate 280, is required, adding a minimum of one component and requiring additional manufacturing steps for forming and attaching the second force plate to the valve head.
While the invention has been described by reference to various specific embodiments, it should be understood that numerous changes may be made within the spirit and scope of the inventive concepts described. Accordingly, it is intended that the invention not be limited to the described embodiments, but will have full scope defined by the language of the following claims.