Information
-
Patent Grant
-
6715466
-
Patent Number
6,715,466
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Date Filed
Monday, December 17, 200123 years ago
-
Date Issued
Tuesday, April 6, 200420 years ago
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Inventors
-
Original Assignees
-
Examiners
Agents
- Wood, Herron & Evans, LLP
- Lundquist; Steve D
-
CPC
-
US Classifications
Field of Search
US
- 123 322
- 123 321
- 123 320
- 123 323
- 123 324
- 123 9012
- 123 9011
-
International Classifications
-
Abstract
An exhaust valve apparatus for an internal combustion engine exhaust valve having a thermally prestressed bender actuator, which moves through a displacement in response to a command signal from a control unit. An actuator drive responsive to motion of the thermally prestressed bender actuator operates an exhaust valve actuator system, which, in turn, operates the exhaust valve. The thermally prestressed electroactive bender actuator and the exhaust valve actuator system operate the exhaust valve to effect engine compression braking.
Description
TECHNICAL FIELD
This invention relates generally to valve actuators and, more particularly, to an apparatus and method for accurately controlling movement of an internal combustion engine exhaust valve in a compression braking cycle.
BACKGROUND
Internal combustion engines, both two cycle and four cycle, utilize reciprocating intake valves to supply a combustible gas to a combustion chamber. Reciprocating exhaust valves are used to exhaust gasses of combustion from the combustion chamber. For many years, a camshaft driven by the main crankshaft of the engine exclusively controlled the operation of the intake and engine valves. With ever increasing demands for improved engine performance over the years, this fixed and inflexible operation of the intake and engine valves with respect to the combustion cycle of the engine proved to be a disadvantage. For example, it is often desirable to adjust the valve timing for different engine operating conditions and/or engine speeds.
In one such application, it is often desirable to use engine compression braking to provide supplemental braking for vehicles traveling down hills. With engine compression braking, the engine is used as an energy absorbing air compressor, and it is necessary to operate the exhaust valves independently of their normal power generating combustion cycle. Thus, the exhaust valves are operated by actuators independent of the rocker arms or other devices operating the exhaust valves during a power generation mode.
More specifically, in a known normal engine compression braking mode, the fuel system is turned off; and the exhaust valve is closed during the compression stroke in the normal manner. However, when the piston is close to the top-dead-center position, the exhaust valve is opened; and the compressed air is vented out of the exhaust system. Thus, energy is absorbed in the compression of the air, but the compressed air is released before the energy can be recovered by the engine.
In another known engine compression braking mode, the exhaust valve is opened near the end of a prior intake stroke, that is, around the bottom-dead-center position. After some crankshaft rotation, such as about 30° for example, the exhaust valve is again closed. Opening the exhaust valve at the end of the intake stroke admits a pulse of high pressure exhaust gases into the combustion chamber for a supercharging effect. The higher initial combustion chamber density then results in greater compression and greater braking power generated during the compression breaking event. As with the normal engine compression braking, the exhaust valve is again opened around the top-dead-center position to vent the compressed gases.
As will be appreciated, the operation of an exhaust valve during a compression braking operation is different than the exhaust valve operation during normal engine operation. In order to provide this varied valve operation, it is known to open and close the exhaust valves by electronically operated hydraulic actuators. The flow of hydraulic fluid to a hydraulic actuator is normally controlled by an electromagnetic solenoid. While such solenoids provide large forces and have long strokes, solenoids do have certain drawbacks. For example, first, during actuation, current must be continuously supplied to the solenoid in order to maintain the solenoid in its energized position. Further, to overcome the inertia of the armature and provide faster response times, a solenoid is driven by a stepped current waveform. A very large current is initially provided to switch the solenoid; and after the solenoid has changed state, the drive current is stepped down to a minimum value required to hold the solenoid in that state. Thus, a relatively complex and high power current driver is required.
In addition to requiring a relatively complex and high current power source, the requirement of continuous current flow to maintain the solenoid at its energized position leads to heating of the solenoid. The existence of such a heat source, as well as the ability to properly dissipate the heat, often is of concern depending on the environment in which the solenoid is used.
Second, the force produced by a solenoid is dependent on the air gap between the armature and stator and is not easily controlled by the input signal. This makes the solenoid difficult to use as a proportional actuator. Large proportional solenoids are common, but they operate near or at the saturation point and are very inefficient.
Third, small, relatively fast acting nonproportional solenoids may have response times defined by the armature displacement as fast as 350 microseconds. However, this response time can be a significant limitation in applications that require high repetition rates or closely spaced events. Further, it is known that there is a substantial delay between the start of the current signal and the start of the armature motion. This is due to the inductive delay between the voltage and magnetic flux required to exert force on the armature. In control systems, such delays lead to variability.
SUMMARY OF THE INVENTION
In accordance with the principles of the present invention, an electrohydraulic actuator for operating an exhaust valve of an internal combustion engine to provide engine compression braking is disclosed. A thermally prestressed electroactive bender actuator has at least two operating states and switches between those states in response to a command signal. An exhaust valve actuator system is coupled with the thermally prestressed electroactive bender actuator and the exhaust valve. The exhaust valve actuator system operates the exhaust valve as a function of the at least two operating states of the thermally prestressed electroactive bender actuator. The thermally prestressed electroactive bender actuator and the exhaust valve actuator system operate the exhaust valve to effect engine compression braking.
BRIEF DESCRIPTION OF THE DRAWINGS
The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and, together with a general description of the invention given above and the detailed description of the embodiments given below, serve to explain the principles of the invention.
FIG. 1
is a schematic block diagram of an exhaust valve electrohydraulic actuator in accordance with one embodiment of the invention.
FIG. 2
is a partial perspective view illustrating one embodiment of the exhaust valve electrohydraulic actuator of FIG.
1
.
FIGS. 3A and 3B
are schematic cross-sectional illustrations of the operation of one embodiment of the exhaust valve electrohydraulic actuator of FIG.
1
.
FIGS. 4A and 4B
are schematic cross-sectional illustrations of the operation of an alternative embodiment of the exhaust valve electrohydraulic actuator of FIG.
1
.
DETAILED DESCRIPTION
With reference to
FIG. 1
, an exhaust valve electrohydraulic actuator
20
according to one embodiment of the invention has an exhaust valve actuator system
21
operating in response to an electromechanical actuator, such as a thermally prestressed electroactive bender (“TPEB”) actuator
24
for example. The exhaust valve actuator system
21
is comprised of an actuator drive
25
and an exhaust valve actuator
32
. The actuator drive
25
is fluidly coupled to a source of pressurized fluid
28
and typically comprises a main valve
30
and a hydraulic pilot valve
26
responsive to the operation of the TPEB actuator
24
. The actuator drive
25
controls the operation of an exhaust valve actuator
32
that, in turn, operates an exhaust valve
34
.
In general, to operate the exhaust valve
34
, an electronic control unit
22
operatively connected to the exhaust valve electrohydraulic actuator
20
provides a command signal to the TPEB actuator
24
causing the TPEB actuator
24
to move through a displacement and switch from a more domed, first state to a less domed, second state. In response thereto, the exhaust valve actuator system
21
switches from a first state to a second, valve operating state as a function of a change in state of the TPEB actuator
24
. More specifically, the change in state of TPEB actuator
24
causes the actuator drive
25
to switch from a first state in which the exhaust valve actuator
32
is held in a first, inoperative to a second operating state that, in turn, causes the exhaust valve actuator
32
to switch to a second, operating state. Switching the exhaust valve actuator
32
between its states causes the exhaust valve
34
to be operated, that is, opened and closed.
In further detail, as the TPEB actuator
24
moves through its displacement, it also moves the hydraulic pilot valve
26
. Movement of the hydraulic pilot valve
26
causes the hydraulic main valve
30
to change states, which, in turn, operates or switches the state of an exhaust valve actuator
32
. The exhaust valve actuator
32
is typically mechanically coupled to the exhaust valve
34
; and thus, the exhaust valve
34
is operated in response to the exhaust valve actuator
32
switching states. Thus, the bidirectional capability of the TPEB actuator
24
within the exhaust valve electrohydraulic actuator
20
may be used to switch a mechanical actuator
34
, such as an exhaust valve for example.
FIG. 2
is a partial perspective view illustrating one embodiment of the exhaust valve electrohydraulic actuator
20
of the invention. A rocker arm assembly
33
has a plurality of independently pivoting rocker arms
35
which are normally operated directly or indirectly by lobes of a camshaft (not shown) in a known manner. It should be noted that
FIG. 2
is presented to show the operation of an exhaust valve system and therefore, is not a comprehensive representation of the full rocker arm assembly
33
. Generally, some rocker arms operate intake valves, and other rocker arms operate exhaust valves. The distal end of the rocker arm
35
is typically in mechanical communication with a center portion of a bridge
36
having two ends. Each end of the bridge is in mechanical communication with an end of a stem of an exhaust valve
34
. A valve return spring
37
is associated with each exhaust valve
34
and biases the exhaust valve
34
towards its closed position. A valve return spring clip or retainer
38
is secured onto the end of the stem of the exhaust valve
34
in a known manner.
Referring to
FIG. 3A
, in one embodiment of the invention, the exhaust valve actuator
32
is mounted on a body or pedestal
39
and is in mechanical communication with the end of the stem of the exhaust valve
34
. An actuator drive
25
may also be mounted on the pedestal
39
and responds to electric or other signals received from an output
23
of the control unit
22
. The pedestal
39
supports the actuator drive
25
and actuator
32
in their proper positions with respect to exhaust valve
34
. The actuator drive
25
causes the exhaust valve actuator
32
, such as a piston and cylinder for example, to operate, thereby opening and closing the exhaust valve
34
.
FIG. 3A
illustrates one embodiment of the invention in which the exhaust valve
34
is operated in response to actuation of the TPEB actuator
24
. In accordance with the principles of the present invention, the TPEB actuator
24
comprises a thermally pre-stressed electroactive bender actuator that changes its shape by deforming in opposite axial directions in response to a control signal applied by the control unit
22
. The TPEB actuator
24
typically has a circular or disk configuration and includes at least one electroactive layer (not shown) positioned between a pair of electrodes (not shown), although other configurations are possible as well without departing from the spirit and scope of the present invention. In a first state, the TPEB actuator
24
is preferably thermally pre-stressed to have a domed configuration as shown in FIG.
3
A. When the electrodes are energized to place the TPEB actuator
24
in a second state, the TPEB actuator
24
displaces axially to a less domed configuration as shown in FIG.
3
B.
Examples of TPEB actuators
24
suitable for use in the present invention are described in U.S. Pat. Nos. 5,471,721 and 5,632,841. The TPEB actuator
24
also may be a model TH-5C commercially available from Face International, Inc. of Norfolk, Va. Other appropriate actuators may also be used. One or more TPEB actuators
24
may comprise a plurality of benders actuators (configured in parallel or in series) that are individually stacked or bonded together into a single multi-layered element.
The TPEB actuator
24
is disposed within a cavity
42
within the housing
40
and is supported at its peripheral edge
44
between lower and upper clamp rings
46
,
48
, respectively. The clamp rings are normally made from a stiff electrically nonconductive material. The lower clamp ring
46
is generally L-shaped and has a generally cylindrical inner locating surface
50
that locates the peripheral edge
44
of the TPEB actuator
24
. The lower clamp ring
46
has an annular support surface
52
that supports one side of the TPEB actuator
24
around its peripheral edge
44
. The upper clamp ring
48
is also generally L-shaped and has a bearing surface
54
that contacts an opposite side of the TPEB actuator
24
around its peripheral edge
44
.
The TPEB actuator
24
is prestressed with a clamping force, typically, between about 0.1 and 300 Newton's, depending on the application. A load ring
56
threadedly engaged within the cavity
42
supplies the clamping force. As the load ring
56
is tightened and loosened, the application of the clamping force is respectively increased and decreased on the peripheral edge
44
of the TPEB actuator
24
via the upper clamp ring
48
. In the embodiment of
FIG. 3A
, the load ring
56
applies a clamping force around the whole peripheral edge
44
of the TPEB actuator
24
. Increasing the clamping force on the TPEB actuator
24
reduces an axial displacement of the TPEB actuator
24
in response to a given control signal magnitude. Decreasing the clamping force results in a greater displacement.
As will be appreciated, in an alternative embodiment, the bearing surface
54
of the upper clamp ring
48
may be notched or cut out at different locations around its circumference. Thus, no clamping force is applied directly to the portions of the peripheral edge
44
of the TPEB actuator
24
that are beneath the cut outs in the bearing surface
54
of the upper clamp ring
48
. In other embodiments, the TPEB actuator peripheral edge
44
can be loaded with a spring or by other means.
The hydraulic pilot valve
26
is comprised of a movable valve
60
, such as a poppet valve for example, disposed in a cavity
62
of a valve body
64
on which the housing
40
is mounted. The hydraulic pilot valve
26
of
FIG. 3A
is a three-way two-position valve. As will be appreciated other comparable functioning valves may be used in place of the poppet
60
.
The housing
40
has an inlet port
65
fluidly coupled with the pressurized hydraulic fluid source
28
(FIG.
1
). Hydraulic fluid provided under a pressure from the pressurized hydraulic fluid source
28
passes through first and second internal fluid passages
67
,
68
, respectively, that intersect cavity
62
of the housing
40
. Hydraulic fluid is returned to the fluid source
28
via drain passages
70
that also intersects the cavity
62
. Operation of the hydraulic pilot valve
26
connects either the supply passage
68
or the drain passage
70
to a control passage
72
. As will be appreciated, the two-dimensional depiction of the passages
68
,
70
,
72
in
FIG. 3A
are schematic in nature. Often the hydraulic pilot valve
26
is manufactured such that the passages
68
,
70
and
72
intersect the cavity
62
at different circumferential locations of the cavity
62
.
In
FIG. 3A
, the TPEB actuator
24
is illustrated in its domed first state or position; and the poppet valve
60
is shown in its first position. The first state of the TPEB actuator
24
is achieved in response to the control unit
22
providing a first command signal to the TPEB actuator
24
, such as a DC biasing voltage of a first polarity. When in that state, a center portion
74
of the TPEB actuator
24
is displaced vertically upward to a flexed or domed position. An actuating pin or portion
76
of the poppet valve
60
is mechanically biased against a lower side of the center portion
74
of the TPEB actuator
24
by a biasing element, such as a return spring
78
for example. As will be appreciated, in alternative embodiments, the actuating pin may be attached to the lower side of the of the center portion
74
of the TPEB actuator
24
by a fastener, bonding agent or other means. With such embodiments, the return spring
78
can be eliminated.
The actuating pin
76
is normally made from an electrically nonconducting material, such as zirconia for example. As will be appreciated, the actuating pin may be fabricated from other electrically insulating materials known to those who are skilled in the art. Alternatively, the end of the actuating pin
76
that is in contact with the TPEB actuator
24
may be constructed to have an electrically nonconductive tip with the remainder of the actuating pin
76
being made of a conductive material. In an alternative embodiment, the actuating pin may be made of a conductive material, and a nonconductive coating applied to at least the center portion
74
the lower side.
In the first position, the poppet valve
60
has a first annular sealing area
80
that is separated from an annular lower seat
82
on the valve body
64
. Therefore, pressurized hydraulic fluid is released to flow from the supply passage
68
to the control passage
72
. When in the first position, the poppet valve
60
has a second annular sealing area
84
that is engaged with an annular upper seat
86
, thereby blocking the flow of hydraulic fluid from the control passage
72
to the drain passage
70
.
When in a first position illustrated in
FIG. 3A
, the poppet valve
60
provides fluid communication between the supply passage
68
and the control passage
72
that in turn, provides hydraulic fluid to a bottom end
90
of a spool valve
92
. The supply passage
68
also intersects an external annular passage or annulus
81
on the spool valve
92
. Holes
83
provide a fluid connection between the annulus
81
and a fluid cavity
94
contiguous with an upper end
96
of the spool valve
92
. Thus, the supply passage
68
provides pressurized fluid to the cavity
94
. A hole
95
is centrally located through the spool valve upper side
96
and intersects a cavity
97
inside the spool valve
92
. The hole
95
permits pressurized hydraulic fluid to flow into the cavity
97
and apply a force opposite the force applied by the pressurized hydraulic fluid on the spool valve upper side
96
. In that way, the forces exerted by the pressurized hydraulic fluid on the lower and upper ends,
90
,
96
, respectively, can be balanced.
With equal fluid pressures on its bottom and upper ends
90
,
96
, respectively, the spool valve
92
is biased toward a first, closed position illustrated in
FIG. 3A
by a biasing element
98
, such as a return spring for example. With the spool valve
92
closed, hydraulic fluid in the supply passage
68
is blocked from entering the top of the fluid passage
100
; and therefore, there is no fluid under pressure applied to the exhaust valve actuator
32
. Thus, the return spring
37
holds the exhaust valve
34
in its closed position. With the spool valve
92
in its upper, closed position, the fluid passage
100
is fluidly connected to an annular fluid path or annulus
85
that in turn intersects a drain line
87
. Thus, any fluid pressure in the fluid path
100
is relieved when the spool valve
92
is in its upper, closed position.
As shown in
FIG. 3A
, the actuator drive controls a supply of pressurized hydraulic fluid to the exhaust valve actuator
32
. The fluid passage
100
extends through the actuator drive
25
and its supporting pedestal
39
and intersects fluid passage
102
within the actuator body
104
of actuator
32
. In this embodiment of the invention, the actuator
32
typically comprises a piston
106
slidably mounted within the actuator body
104
. The fluid passage
102
is fluidly coupled with an upper end
108
of the piston
106
. A lower end or side
110
of the piston
106
is mechanically coupled with one end of an actuator pin
112
. An opposite end of the actuating pin
112
extends through one end of the bridge
36
and is mechanically coupled with an end of the stem of the exhaust valve
34
. The exhaust valve
34
is biased to its closed position by the return spring
37
. In a state illustrated in
FIG. 3A
, the absence of pressurized fluid from the pressurized hydraulic fluid source
28
in the fluid paths
100
,
102
permits the exhaust valve
34
to remain in its closed position as biased by the spring
37
. Thus, with the TPEB actuator
24
in its illustrated first or domed state, the exhaust valve
34
is operated by the action of the bridge
36
as required during a normal engine operation.
When it is desired to change the state of the hydraulic pilot valve
26
, the electronic control unit
22
provides a second command signal to the TPEB actuator
24
, such as a DC biasing voltage of a second, typically opposite polarity as the first command signal. Referring to
FIG. 3B
, in one embodiment of the invention, the second command signal causes the TPEB actuator
24
to flex in a first direction, such as a generally vertically downward direction to a less domed or slightly domed position. The downward movement of the TPEB actuator
24
overcomes the biasing force of the return spring
78
as the TPEB actuator
24
moves to its second position or state.
Movement of the TPEB actuator
24
downward pushes the actuator portion
76
and the poppet
60
downward to its second position. With the poppet valve
60
at its second position, the first annular sealing area
80
engages the annular lower seat
82
on the valve body
64
, and pressurized hydraulic fluid from the supply passage
68
is blocked from the control passage
72
. Further, the second annular sealing area
84
is separated from the annular upper seat
86
, thereby opening the control passage
72
to the drain passage
70
. Thus, hydraulic pressure is removed from the bottom end or side
90
of the spool valve
92
. The pressure head in the cavity
94
on the upper end or side
96
of the spool valve
92
overcomes the force exerted by the return spring
98
, and the spool valve
92
moves vertically downward to a second, open position. Movement of the spool valve
92
downward forces hydraulic fluid from the cavity
97
, through the hole
95
and into the cavity
94
. A stationary spool pin
99
positively stops the downward movement of the spool valve
92
.
A displacement of the spool valve
92
to its lower, open position shown in
FIG. 3B
terminates the fluid connection between the fluid path
100
and the annulus
85
and drain
87
. Further, displacement of the spool valve
92
downward opens a fluid path via annulus
81
between the supply passage
68
and the top of the fluid passage
100
. Thus, pressurized hydraulic fluid from the pressurized hydraulic fluid source
28
is applied to fluid passages
100
,
102
and the upper end
108
of the piston
106
. A force sufficient to overcome the force of the return spring
37
is generated, and the piston
106
and actuator pin
112
are moved in a vertically downward direction, thereby moving the valve
34
to the illustrated open position. The opening of the exhaust valve
34
is effected independent of the operation of the bridge
36
and thus, can be used to execute a compression braking cycle.
The exhaust valve electrohydraulic actuator
20
typically remains in the state illustrated in
FIG. 3B
until the electronic control unit
22
determines that the exhaust valve
34
is to be closed. It should be noted that if the second command signal is removed, e.g., reduced to a zero voltage, the capacitive behavior of the TPEB actuator
24
causes it to temporarily remain in the position illustrated in
FIG. 3B
for some period of time. Therefore, substantially less power is required to maintain the TPEB actuator
24
than other actuators, such as a solenoid for example.
When the valve
34
is to be closed, the electronic control unit
22
again provides the first command signal on its output
23
to the TPEB actuator
24
. The first command signal causes the TPEB actuator
24
to move in a second direction opposite the first direction, such as a generally vertically upward direction as viewed in
FIG. 3B
, to its first, more domed, prestressed position or state as illustrated in FIG.
3
A. As the TPEB actuator
24
moves upward, the return spring
78
moves the poppet valve
60
upward, such that the actuating pin
76
remains in contact with the center portion
74
of the TPEB actuator
24
.
Movement of the poppet valve
60
vertically upward back to its first position closes or terminates fluid communication between the control passage
72
and the drain passage
70
and opens the control passage
72
to the supply passage
68
. Pressurized hydraulic fluid in the control passage
72
applies a force against the bottom end
90
of the spool valve
92
. That force in combination with the force of the return spring
98
overcomes the force of the pressurized hydraulic fluid on the upper side
96
of the spool valve
92
. However, a slot
101
in the top of the stationary spool pin
99
facilitates the flow of hydraulic fluid through the hole
95
and into the forming cavity
97
. Thus, as the spool valve
92
moves from its open position, the fluid pressure forces on the bottom and top ends
90
,
96
, respectively, quickly equalize to a balanced state.
With the hydraulic pressure on the spool valve
92
balanced, the return spring
98
holds the spool valve
92
in its closed position. Closing the spool valve
92
terminates the application of pressurized hydraulic fluid to the fluid passages
100
,
102
and the upper end or side
108
of the piston
106
. Further, the fluid path
100
is connected to the drain
87
via the annulus
85
, thereby relieving any hydraulic fluid pressure in the fluid path
100
. The valve return spring
37
is then able to apply a force against the lower end
110
of the piston
106
, which is greater than the reduced fluid pressure force on the upper end
108
of the piston
106
. Thus, the return spring
37
moves the valve
34
and piston
106
in the generally upward direction, and the valve
34
returns to its closed position.
The embodiment illustrated in
FIGS. 3A-3B
provides a controllable exhaust valve electrohydraulic actuator
20
that directly operates an exhaust valve
34
independent of the rocker arm assembly
33
including the bridge
36
. As will be appreciated, the exhaust valve electrohydraulic actuator
20
of
FIG. 1
may be used in an alternative embodiment as illustrated in
FIGS. 4A and 4B
. The operation of the actuator drive
25
is similar to that described with respect to
FIGS. 3A and 3B
. The actuator
32
operates similarly to that described with respect to
FIGS. 3A and 3B
; however, the piston
106
of actuator
32
is mechanically coupled with one end
116
of the rocker arm
118
. The opposite end
120
of the rocker arm
118
is mechanically coupled with an end of the stem of the exhaust valve
34
in a known manner. Thus, in this embodiment, the electronic control unit
22
provides command signals to operate the TPEB actuator
24
, hydraulic pilot valve
26
and main valve
30
, so that hydraulic fluid is ported to the exhaust valve actuator
32
, thereby causing the exhaust valve actuator
32
to raise and lower the rocker arm
118
and respectively open and close the exhaust valve
34
.
The exhaust valve electrohydraulic actuator
20
of
FIGS. 3 and 4
is illustrated as being applied to a single exhaust valve; however, as will be appreciated, in other embodiments of the invention, the exhaust valve electrohydraulic actuator
20
can be replicated for each exhaust valve to be controlled. Similarly, in other embodiments of the invention, the actuator
20
may control multiple exhaust valves. Further, while the above-described embodiment uses the TPEB actuator
24
to operate the exhaust valve
34
, as will be appreciated, the TPEB actuator
24
may be used to operate any of a variety of other actuators found on a vehicle and known to those who are skilled in the art.
The TPEB actuator
24
is a bidirectional device. As will be appreciated, in an alternative embodiment, a hole may be formed in the center portion
74
of the TPEB actuator
24
; and an end of the actuating pin
76
may be attached to the center portion
74
of the TPEB actuator
24
. Thus, the poppet valve
60
can be moved in opposite directions by applying the appropriate command signals to the TPEB actuator
24
as previously described. This embodiment allows for either the elimination of a return spring or the use of a substantially smaller return spring. As will be appreciated, in this embodiment, adhesives or other bonding means may also be used to connect the end of the actuating pin
76
to the center portion
74
of the TPEB actuator
24
. Again, once in that state, the second command signal or bias can be removed, and the capacitive behavior of the TPEB actuator
24
causes it to remain temporarily in the position illustrated in FIG.
3
A.
In the operation of the exhaust valve
34
described in the embodiments herein, the operation of the return spring
37
typically moves the exhaust valve
34
with a relatively high force. Thus, the exhaust valve
34
typically impacts the valve seat
114
at a relatively high velocity. Such repeated high velocity impact of the exhaust valve
34
on the seat
114
causes wear and reduces the life of the exhaust valve
34
. The TPEB actuator
24
is a proportional and bidirectional actuator, and those features can be used to cushion or reduce the impact of the exhaust valve
34
on the seat
114
.
After the second command signal is provided to the TPEB actuator
24
to move it back toward its first position as illustrated in
FIG. 3A
, the exhaust valve
34
is moved towards the seat
114
by the return spring
37
. As the exhaust valve
34
moves toward its seat, the electronic control unit
22
may apply a third command signal or bias similar to, but typically of a reduced magnitude than, the first command signal. The third command signal causes the TPEB actuator
24
to move through a small displacement downward to an intermediate less domed third position. This movement allows the poppet valve
60
to move slightly which permits a slight bleeding of fluid pressure through the drain passage
70
and a slight movement of the spool valve
92
downward.
The slight movement of the spool valve
92
reapplies pressurized hydraulic fluid to the fluid paths
100
,
102
and the upper end or side
108
of the piston
106
. This operation provides a resistance force on the piston
106
against the operation of the return spring
37
moving the exhaust valve
34
to the closed position. With the resistance force, the velocity of the exhaust valve
34
is reduced, as is the impact force of the exhaust valve
34
on the seat
114
. As will be appreciated, the electronic control unit
22
can provide command signals to the TPEB actuator
24
that control the position, velocity and/or acceleration of the TPEB actuator
24
in order to more precisely control the operation of the exhaust valve
34
in moving to the opened and closed positions.
Industrial Applicability
The present invention provides an exhaust valve electrohydraulic actuator
20
using a TPEB actuator
24
as a mechanical power source for the exhaust valve electrohydraulic actuator
20
. The TPEB actuator
24
is physically small, uses relatively little power, has very fast response times and has a proportionally controllable bidirectional operation. Thus, an exhaust valve electrohydraulic actuator
20
is provided in which the exhaust valve operation with respect to the engine combustion cycle is virtually unlimited.
Further, the use of a TPEB actuator
24
in an exhaust valve electrohydraulic actuator
20
provides significant advantages over electromagnetic solenoids. First, its small mass and low inertia provides the TPEB actuator
24
with extremely fast response times, such as about 150 microseconds. The fast response time TPEB actuator
24
reduces the indeterminate time that the exhaust valve
34
is between states and provides a reduced cycle time in the operation of the exhaust valve
34
. The reduced cycle time of the exhaust valve
34
has the advantage of providing a more consistent and less variable operation of the exhaust valve
34
, thereby resulting in a more consistent, predictable and reliable operation of the engine.
Thus, in a normal engine compression braking mode, the exhaust valve
34
can be closed by the rocker arm assembly
33
during the compression stroke in a normal manner. However, when the piston is close to the top-dead-center position, the exhaust valve
34
can be opened independently of the rocker arm assembly
33
using the TPEB actuator
24
. The fast response time of the TPEB actuator
24
results in the exhaust valve
34
being opened at precisely the same time with each compression stroke. This high degree of precision and repeatability in the operation of the exhaust valve
34
results in a consistent and highly effective engine compression braking.
Further, the fast response time of the TPEB actuator
24
permits operation of the exhaust valve over very short intervals. Thus, the engine exhaust valve actuator
32
can perform multiple cycles of the exhaust valve
34
within a single engine cycle. This capability is especially useful in performing the alternate mode of engine compression braking in which the exhaust valve
34
is opened twice during a compression stroke. Again, the fast response time the TPEB actuator
24
provides a more precise and repeatable operation of exhaust valve
34
, thereby providing a more consistent and effective engine compression braking event.
A TPEB actuator
24
has a further advantage of having a capability of proportional, bidirectional operation. Thus, the TPEB actuator
24
allows for very precise positioning of the hydraulic pilot valve
26
, thereby providing a very precise control of the main valve
30
. Precise control of the main valve
30
permits a precise control of the exhaust valve actuator
32
and exhaust valve
34
.
In addition, the capability of proportional bidirectional control provides an exhaust valve electrohydraulic actuator
20
that has the capability of adjusting the velocity of the exhaust valve
34
as it returns to its seat
114
upon closing. In this application, the pilot stage
26
can be operated to move the main valve
30
slightly in a direction to slow the return of the exhaust valve
34
right before it reaches its seat
114
, thereby cushioning the impact of the exhaust valve
34
.
The TPEB actuator
24
has a still further advantage in that it draws considerably less power than an electromagnetic solenoid. Further, due to its capacitive behavior, a TPEB actuator
24
draws no power during a hold period where actuation is temporarily maintained for a period of time.
Although the TPEB actuator
24
is somewhat limited in force capability, multiple TPEB actuators may be easily combined in a stacked, parallel manner to provide a greater force that is approximately linearly related to the number of actuators in the stack. In addition, TPEB actuators may be combined in a serial manner to increase the magnitude of the stroke, that is, the displacement. Even in a stacked arrangement, TPEB actuators are relatively small and take up substantially less space than electromagnetic solenoids.
Even though the above describes an exhaust valve electrohydraulic actuator
20
that uses a TPEB actuator
24
, those of ordinary skill in the art will appreciate that the exhaust valve electrohydraulic actuator
20
is readily adaptable for use in a wide range of applications without departing from the spirit and scope of the present invention.
While the present invention has been illustrated by a description of various embodiments, and while these embodiments have been described in considerable detail, it is not the intention of Applicants to restrict or in any way limit the scope of the appended claims to such detail. Additional advantages and modifications will readily appear to those skilled in the art.
Thus, the invention in its broader aspects is, therefore, not limited to the specific details, representative apparatus and method, and illustrative example shown and described. Accordingly, departures may be made from such details without departing from the spirit or scope of Applicants' general inventive concept.
Other aspects and features of the present invention can be obtained from a study of the drawings, the disclosure, and the appended claims.
Claims
- 1. An apparatus for operating an exhaust valve of an internal combustion engine, the apparatus comprising:a thermally prestressed electroactive bender actuator configured to receive a command signal and responsively move between first and second positions; and an exhaust valve actuator system coupled with the thermally prestressed electroactive bender actuator and the exhaust valve, the exhaust valve actuator system configured to operate the exhaust valve as a function of the thermally prestressed electroactive bender actuator moving between the first and second positions; wherein the exhaust valve actuator system includes an actuator drive coupled with the thermally prestressed electroactive bender actuator, the actuator drive having at least one hydraulically actuated valve.
- 2. The apparatus of claim 1 wherein the exhaust valve actuator system is operable to open and close the exhaust valve as a function of the thermally prestressed bender actuator moving between the first and second positions.
- 3. The apparatus of claim 1 whereinthe actuator drive is operable to change state as a function of the thermally prestressed electroactive bender actuator moving between the first and second positions, and further including; an exhaust valve actuator coupled with the actuator drive and the exhaust valve, the exhaust valve actuator operable to operate the exhaust valve as a function of the actuator drive changing state.
- 4. The apparatus of claim 3 wherein the actuator drive provides a flow of a pressurized fluid representing a first state in response to the thermally prestressed electroactive bender actuator moving from the first position to the second position, and the actuator drive terminates the flow of a pressurized fluid representing a second state in response to the thermally prestressed electroactive bender actuator moving from the second position to the first position.
- 5. The apparatus of claim 4 wherein the exhaust valve actuator opens the exhaust valve in response to the flow of the pressurized fluid and closes the exhaust valve in response to an absence of the flow of the pressurized fluid.
- 6. The apparatus of claim 1 wherein the least one hydraulically actuated valve comprises:a pilot valve coupled with the thermally prestressed electroactive bender actuator, the pilot valve operable to switch between first and second operating states as a function of the operating states of the thermally prestressed electroactive bender actuator; and a main valve coupled with the pilot valve, the main valve operable to switch between first and second operating states as a function of the operating states of the pilot valve.
- 7. The apparatus of claim 6 wherein the pilot valve is mechanically coupled with the thermally prestressed electroactive bender actuator and the pilot valve is moved by the thermally prestressed electroactive bender actuator moving between the first and second positions.
- 8. The apparatus of claim 7 wherein the pilot valve is fluidly coupled with the main valve, and the main valve is operable to control a supply of pressurized fluid to the exhaust valve actuator to operate the exhaust valve as a function of the pilot valve being moved by the thermally prestressed electroactive bender actuator moving between the first and second positions.
- 9. The apparatus of claim 6 wherein the thermally prestressed electroactive bender actuator moves through a displacement in a first direction in response to a first command signal.
- 10. The apparatus of claim 9 wherein in response to the thermally prestressed electroactive bender actuator moving through a displacement in the first direction, the pilot valve moves in a first direction, the pilot valve operable to cause the main valve to supply pressurized fluid to the exhaust valve actuator that, in turn, is operable to cause the exhaust valve to open.
- 11. The apparatus of claim 10 wherein the thermally prestressed electroactive bender actuator moves through a displacement in an opposite direction in response to a second command signal.
- 12. The apparatus of claim 11 wherein in response to the thermally prestressed electroactive bender actuator moving through a displacement in the opposite direction, the pilot valve moves in an opposite direction, thereby causing the main valve to terminate a supply of pressurized fluid to the exhaust valve actuator, whereby the exhaust valve is closed.
- 13. The apparatus of claim 6 wherein the pilot valve comprises a poppet valve.
- 14. An apparatus for operating an exhaust valve of an internal combustion engine in response to command signals to provide engine compression braking, the apparatus comprising:a thermally prestressed electroactive bender actuator operable to move through displacements in two different directions as a function of the command signals; and an exhaust valve actuator system coupled with the thermally prestressed electroactive bender actuator operable to operate the exhaust valve, the exhaust valve actuator system including an actuator drive having at least one hydraulically actuated valve, and operating the exhaust valve as a function of the thermally prestressed electroactive bender actuator moving through the displacements, the thermally prestressed electroactive bender actuator and the exhaust valve actuator system operable to operate the exhaust valve to effect engine compression braking.
- 15. The apparatus of claim 14 wherein the thermally prestressed electroactive bender actuator is operable to move through a displacement in a first direction as a function of a first command signal and to move through a displacement in a second direction as a function of a second command signal.
- 16. The apparatus of claim 14 wherein the exhaust valve actuator system is operable to move the exhaust valve to an open position as a function of the thermally prestressed electroactive bender actuator moving through a displacement in the first direction, and to move the exhaust valve to a closed position as a function of the thermally prestressed electroactive bender actuator moving through a displacement in the second direction.
- 17. The apparatus of claim 16 wherein the thermally prestressed electroactive bender actuator is operable to move through a first displacement in the first direction as a function of a first command signal and to move through a second displacement in the first direction as a function of a third command signal.
- 18. An apparatus for operating an exhaust valve of an internal combustion engine in response to a command signal to provide engine compression braking, the apparatus comprising:a control unit operable to provide a plurality of command signals indicative of engine braking; a thermally prestressed electroactive bender actuator electrically connected with the control unit to receive the plurality of command signals, the thermally prestressed bender actuator operable to move through a plurality of displacements in two different directions as a function of the command signals; and an exhaust valve actuator system coupled with the thermally prestressed electroactive bender actuator and the exhaust valve, the exhaust valve actuator system including an actuator drive having at least one hydraulically actuated valve, and operable to operate the exhaust valve as a function of the thermally prestressed electroactive bender actuator moving through the plurality of displacements, the thermally prestressed electroactive bender actuator and the exhaust valve actuator system operable to operate the exhaust valve to effect engine compression braking.
- 19. A method of operating an exhaust valve of an internal combustion engine, the method comprising:applying the command signal to a thermally prestressed electroactive bender actuator; switching the thermally prestressed electroactive bender actuator between first and second operating states as a function of the command signal; and switching at least one hydraulically actuated valve in an actuator drive in an exhaust valve actuator system between first and second operating states as a function of the thermally prestressed electroactive bender actuator switching between the first and the second operating states, the exhaust valve actuator system operating the exhaust valve as a function of the switching of the exhaust valve actuator system.
- 20. The method of claim 19 wherein switching the exhaust valve actuator system further comprises:switching actuator drive between first and second operating states as a function of the thermally prestressed electroactive bender actuator switching between the first and the second operating states; and switching an exhaust valve actuator between first and second operating states as a function of the actuator drive switching between the first and the second operating states.
- 21. The method of claim 20 wherein switching the at least one hydraulically actuated valve further comprises:switching a pilot valve between first and second operating states as a function of the thermally prestressed electroactive bender actuator switching between the first and the second operating states; and switching a main valve between first and second operating states as a function of the pilot valve switching between first and second operating states.
- 22. A method of operating an exhaust valve of an internal combustion engine in response to command signals to provide engine compression braking, the method comprising:applying a first command signal to a thermally prestressed electroactive bender actuator; moving the thermally prestressed electroactive bender actuator through a displacement in a first direction as a function of the first command signal; and supplying a pressurized fluid to at least one hydraulically actuated valve in an actuator drive in an exhaust valve actuator system as a function of the thermally prestressed electroactive bender actuator moving through the displacement in the first direction, the pressurized fluid operable to cause the exhaust valve to open, the thermally prestressed electroactive bender actuator and the exhaust valve actuator system operating the exhaust valve to effect engine compression braking.
- 23. The method of operating an exhaust valve of claim 22 wherein supplying a pressurized fluid to at least one hydraulically actuated valve comprises:moving a pilot valve as a function of the thermally prestressed electroactive bender actuator moving through the displacement in the first direction; and opening a main valve to supply pressurized fluid to the exhaust valve actuator as a function of the pilot valve moving.
- 24. The method of operating an exhaust valve of claim 23 further comprising moving the pilot valve in the first direction in response to the thermally prestressed electroactive bender actuator moving in the first direction.
- 25. The method of claim 22 further comprising:applying a second command signal to the thermally prestressed electroactive bender actuator; moving the thermally prestressed electroactive bender actuator through a displacement in a second direction as a function of the second command signal; and terminating a supply of the pressurized fluid to the exhaust valve actuator as a function of the thermally prestressed electroactive bender actuator moving through the displacement in the second direction, the termination of pressurized fluid operable to cause the exhaust valve to close.
- 26. The method of operating an exhaust valve of claim 25wherein terminating a supply of pressurized fluid comprises: moving the pilot valve as a function of the thermally prestressed electroactive bender actuator moving in the second direction; and closing the main valve to terminate the supply of pressurized fluid to the exhaust valve actuator as a function the pilot valve moving.
- 27. The method of operating an exhaust valve of claim 26 further comprising moving the pilot valve in the second direction in response to the thermally prestressed electroactive bender actuator moving in the second direction.
- 28. The method of claim 25 further comprising:applying a third command signal to the thermally prestressed electroactive bender actuator; and moving the thermally prestressed electroactive bender actuator through a second displacement in the first direction as a function of the third command signal.
- 29. The method of operating an exhaust valve of claim 28 wherein the second direction is a direction opposite the first direction.
US Referenced Citations (23)