The present disclosure relates generally to a rocker arm assembly for use in a valve train assembly and more particularly to a rocker arm assembly having a mechanical latch pin for a deactivating rocker arm assembly capable of full lift, partial lift, or no lift.
Many internal combustion engines utilize rocker arms to transfer rotational motion of cams to linear motion appropriate for opening and closing engine valves. Deactivating rocker arms incorporate mechanisms that allow for selective activation and deactivation of the rocker arm. In a deactivated state, the rocker arm may exhibit lost motion movement. In order to return to an activated state from a deactivated state, the mechanism may require that the rocker arm be in a particular position or within a range of positions that may not be readily achieved while undergoing certain unconstrained movement while in the deactivated state, such as during excessive lash adjuster pump-up.
The background description provided herein is for the purpose of generally presenting the context of the disclosure. Work of the presently named inventors, to the extent it is described in this background section, as well as aspects of the description that may not otherwise qualify as prior art at the time of filing, are neither expressly nor impliedly admitted as prior art against the present disclosure.
The methods and devices disclosed herein overcome the above disadvantages and improves the art by way of a rocker arm assembly comprising a valve side rocker arm portion, a cam side rocker arm portion configured to selectively rotate relative to the valve side rocker arm portion, and a latch pin assembly disposed in the valve side rocker arm portion and in the cam side rocker arm portion. A latch pin assembly is disposed for selective switching in the valve side latch bore and in the cam side latch bore. At least a portion of the latch pin assembly is configured so that when the latch pin assembly is selected to switch from a latched condition to the unlatched condition, and when the cam side rocker arm portion selectively rotates, the latch pin assembly is configured to retract from the forces of the rotation.
The latch pin assembly comprises a primary latch pin assembly disposed in the valve side rocker arm portion opposite a secondary latch pin assembly disposed in the cam side rocker arm portion. The valve side rocker arm portion comprises a primary oil control cavity in a valve side body, and the primary latch pin assembly is configured to telescope in and out of the primary oil control cavity. The primary latch pin assembly comprises a first primary pin nested in a channel of the primary oil control cavity and a second primary pin nested in a channel of the first primary pin. The valve side body comprises an oil channel configured to supply oil pressure to the primary oil control cavity. A first biasing member is configured to bias the second primary pin out of the first primary pin.
The cam side rocker arm portion comprises a secondary oil control cavity in a cam side body, and the secondary latch pin assembly is configured to telescope in and out of the secondary oil control cavity. The secondary latch pin assembly comprises a first secondary pin nested in a channel of the secondary oil control cavity and a second secondary pin nested in a channel of the first secondary pin. The cam side body comprises an oil channel configured to supply oil pressure to the secondary oil control cavity. The oil channel in the valve side body is configured to supply oil pressure to the oil channel in the cam side body. A second biasing member is configured to bias the first secondary pin out of the cam side rocker arm portion. The valve side rocker arm portion comprises a rim around the primary latch pin assembly, and the secondary latch pin assembly is configured to telescope out of the cam side rocker arm portion and into the rim. A portion of the secondary latch pin assembly is configured to telescope out of the cam side rocker arm portion and into a portion of the primary latch pin assembly.
The rocker arm assembly can be configured wherein the cam side rocker arm portion comprises a secondary oil control cavity in a cam side body, wherein the secondary latch pin assembly comprises a first secondary pin nested in a channel of the secondary oil control cavity and a second secondary pin nested in a channel of the first secondary pin, and wherein the second secondary pin is configured to telescope out of the channel of the first secondary pin and into the channel of the first primary pin.
The cam side rocker arm portion can be configured to pivot past the valve side rocker arm portion when the primary latch pin assembly opposes the secondary latch pin assembly when the latch pin assembly is unlatched.
A rocker arm assembly can comprise a valve side rocker arm configured to rotate about a pivot location and a cam side rocker arm configured to selectively rotate about the pivot location relative to the valve side rocker arm portion. The valve side rocker arm can comprise a valve side channel in a valve side latch bore. The cam side rocker arm can comprise a cam side channel in a cam side latch bore. A latch pin assembly can comprise a first latch pin assembly in the cam side latch bore and a second latch pin assembly in the valve side latch bore, wherein the latch pin assembly comprises at least one edge feature configured to reduce contact stresses when the cam side rocker arm selectively rotates. One or both of the first latch pin assembly and the second latch pin assembly can comprise two edge features configured to reduce contact stresses when the cam side rocker arm selectively rotates.
The latch pin assembly can find application in other types of rocker arms, though it is shown in a type III rocker arm. The latch pin assembly can comprise additional aspects, including contact-stress reducing and self-retracting features. So, in addition to latch and lash management aspects, the latch pin assembly provides lower stress, critical shift mitigation, and latch retention aspects. The design yields manufacturing benefits including cost-effective designs for manufacturing the latch bores.
Additional objects and advantages will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of the disclosure. The objects and advantages will also be realized and attained by means of the elements and combinations particularly pointed out in the appended claims.
It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the claimed invention.
Reference will now be made in detail to the examples which are illustrated in the accompanying drawings. Directional references such as “left” and “right” are for ease of reference to the figures.
With reference to
The rocker arm assembly 10 is shown as a type III, center pivot. It can comprise a roller bearing 9 on a bearing axis 8 for interfacing with a cam rail. A cam lobe on the cam rail can impart a valve lift profile to the rocker arm assembly 10. A tappet interface can substitute for the roller bearing 9 and bearing axis 8.
The cam side rocker arm portion 14 and the valve side rocker arm portion 12 can pivot with respect to one another, rotating around a pivot axle 7. Or, the pivot location for the cam side rocker arm portion 14 and the valve side rocker arm portion 12 can be shared about the rocker shaft bore 3, as by extending the material of the cam side rocker arm portion 14 around the rocker shaft bore and eliminating the pivot axle 7. Then, rotation is around the rocker shaft.
A spring 6 can be biased between the cam side rocker arm portion 14 and the valve side rocker arm portion 12. The spring can enable lost motion valve lift profiles, including zero lift profiles, as described more below, when the latch pin assembly 20 is configured for lost motion.
The valve side rocker arm portion 12 can comprise a variety of additional aspects such as a lash adjuster, deactivating capsule, engine brake capsule, among others as by an insert 5. An engine valve stem can connect directly or indirectly at an elephant foot (e-foot) 4 or the like, and valve bridges and other valve connections can be used.
The rocker shaft bore 3 can couple to a rocker shaft and the rocker shaft can be configured to supply pressurized control fluid to the rocker arm assembly 10. Then, internal oil channels 200-204 can supply control fluid. For example, oil channel 202 can supply control fluid to enable hydraulic lash adjustment in the insert 5, or to enable engine braking or cylinder deactivation functionality, as per the insert 5. Oil channel 200 in valve side latch body 240 of valve side rocker arm portion 12 can supply control fluid to the latch pin assembly 20. Oil channel 201 in cam side latch body 242 can supply a separate control fluid. Oil channels 200-202 connect to receive fluid from the rocker shaft bore 3, and oil channels 203, 204 can be formed for additional functionality, such as an EEVO (early exhaust valve opening) control fluid. The oil channels 200-204 can be drilled or cast or otherwise formed into the rocker arm assembly 10, and in some alternatives plugs 1, 1170 can be used to fluidly seal an end of the oil channel, as shown for oil channel 200 in
A slot 30 is defined in the cam side rocker arm portion 14. The latch pin assembly 20 engages the slot 30 in a way that is normally latched and allows for lost motion when disengaged, and also engages in a way as referred to herein as partially engaged. Slot 30 comprises on one side, shown in body portion 240 of valve side rocker arm portion 12, a primary oil control cavity 70. On the other side of slot 30, shown in body portion 242 of cam side rocker arm portion 14, a secondary oil control cavity 72 is formed. Latch pin assembly 20 is nested in slot 30 and comprises telescoping aspects to interface with channels 440, 540, 4400, 5400, 701, 722, 1701, 1722 and rims 401, 402, 4010, 4020 to provide at least two valve lift profiles to one or more valves coupled to the rocker arm, and to provide at least three valve lift profiles.
Referring now to
A first end 441 of first primary pin 44 can abut a back wall 1700 of oil control cavity 70 in
Outward surface 462 of first secondary pin 46 can be biased towards secondary latch pin assembly 42 by first biasing member 60 in a cavity 461. Outward surface 562 of second secondary pin 56 can be biased towards primary latch pin assembly 40 by the second biasing member 62 and by oil pressure to gland communicating with secondary oil control cavity 72. The blind bore 68 can be oil fed by oil channel 201. Lock ring 66 can seat second secondary pin 56. And, secondary pin 56 can be opposed and positioned in secondary channel 540 by oil pressure to second primary pin 46.
With reference to
Comparing
With reference now to
Outward surface 1462 of first secondary pin 146 can be biased towards secondary latch pin assembly 142 by first biasing member 160. Outward surface 1562 of second secondary pin 156 can be biased towards primary latch pin assembly 140 by the second biasing member 162 and by oil pressure to gland communicating with secondary oil control cavity 172. The blind bore 168 can be oil fed by oil channel 201. Lock ring 166 can seat second secondary pin 156. And, secondary pin 156 can be opposed and positioned in secondary channel 1540 by oil pressure to second primary pin 146.
A first end 1441 of first primary pin 144 can abut a back wall 1700 of oil control cavity 170 in
Turning to
In reference to
In reference to
Another kind of “lost motion” is shown in
With reference to
In
A first end 1441 of primary latch pin assembly 1140 can abut an inner surface of plug 1170 when oil pressure is applied through oil port 1201 in the unlatched position of latch pin assembly 21. In the unlatched position, lift forces from cam 2 get lost, because the cam side arm 1114 can move without transferring forces to the valve side arm 1112. However, in the latched position, the latch pin assembly 21 locks the cam side arm 1114 and valve side arm 1112 together so that lift forces from the cam 2 are transferred to the valve end 4 of the rocker arm 1110.
First biasing member 1160 can be seated against a seat 11170 in plug 1170 to push the primary latch pin assembly 1140 towards the latched position. The latched position comprises the primary latch pin assembly 1140 extending from primary channel 11701 into secondary channel 11722. A relief port 1171 in plug 1170 can serve as a wrench coupling for threading the plug 1170 to threads in primary channel 11701. Relief port 1171 can also emit oil that leaks through the latch pin assembly, as from valve side latch bore to cam side latch bore.
To enter the unlatched position, oil port 1201 communicates with oil control cavity 1172 for providing oil pressure to selectively push secondary latch pin assembly 1142 away from back wall 11720 of oil control cavity 1172. First end 11541 of secondary latch pin assembly 1142 can be configured with a knurl 11543 to space the first end 11541 away from the back wall 11720, which can help with stiction. The knurl 11543 serves as a stop feature and it allows oil to engage the first end 11541 of the secondary latch pin assembly 1142 in a way that improves the response time and avoids gage blocking. Oil pressure pushes the secondary latch pin assembly 1142 towards the cam side arm 1114 so that primary latch pin assembly 1140 slides out of secondary channel 11722 and through primary channel 11701. The first biasing member 1160 can be compressed. With enough force, first end 11441 of primary latch pin assembly 1140 can abut plug 1170.
The latch pin assembly 21 offers several advantages. For example, it is possible to align the cam side arm 114 with the valve side arm 1112 and drill both bores for the latch pin assembly 21 at the same time. Then, concentricity is assured for the channels 11701 & 11722. The pieces of the latch pin assembly 21 are assured to align, and a drop-in assembly method can be achieved. Also, lash can be set during the drilling process. This can avoid critical shifts. And, the plug 1170 can be threaded or otherwise set in the cam side latch bore to a depth that sets the travel of primary latch pin assembly 1140 while the relief port 1171 in the plug 1170 provides an additional pathway for overpressure release. The threaded plug 1170 provides an adjustment capability for the primary latch pin 1140 so that when the primary latch pin 1140 is retracted into channel 11701, the gap of distance D1 is preserved.
Even with the advantages of the latch pin assembly 21, it is beneficial to add additional and optional features in the alternative, as seen in latch pin assembly 22. By looking at the simplified assembly of
The second end 11442 of primary latch pin assembly 1140 can include an edge feature 1143, 1146 that helps with the releasing and returning of the primary latch pin assembly 1140 to the latch pin bore of the cam side arm 1114 during the no lift, deactivated state of the unlatched latch pin assembly 21, 22. The edge feature can comprise, for example, a radius, a chamfer, a bevel, a fillet, a round over, a bullnose, or the like. The edge feature is configured to reduce contact stresses. This can include minimizing edge-loading on the latch pin assembly 1140, 1142 as tilting occurs in the corresponding latch bores. That is, as the cam 2 transfers its profile to the cam side arm 1114, the latch assembly can tilt in the cam side latch bore and in the valve side latch bore, and the edge features 1143-1149 can reduce edge loading and other contact stresses on the latch assembly and latch bores. The primary latch pin assembly 1140 can be a pin with a cylindrical shape, and so a round over can be applied at the whole edge of the second end 11442. The pin is not limited to a cylindrical shape. Then, when a channel edge 31722 of secondary channel 11722 presses on the edge feature 1143, 1146, the channel edge 31722 can push the primary latch pin assembly 1140 into primary channel 11701 so that the cam side arm 1114 can pivot with respect to the valve side arm 1112 while the latch pin assembly 21 is unlatched. The channel edge 31722 can comprise a complementary shape, such as a chamfer or radius to act on a chamfer or radius edge feature. In
Additional edge features can be included, as shown in
A gap of distance D1 can be set between the cam side arm 1114 and the valve side arm 1112. Primary latch pin 1140 projects into secondary channel 11722 a distance D3 during latching. Then, a distance D2 can be designed to enable the self-retracting features. So long as the secondary latch pin 1145 can supply oil pressure to push the primary latch pin 1140 to a reset zone of distance D2 overlapping the gap of distance D1 between the cam side arm 114 and the valve side arm 1112, then the channel edge 31701 can push the secondary latch pin 1145 out of the way and the channel edge 31722 can push the primary latch pin 1140 out of the way for unlatched (lost motion). The primary latch pin 1140 can project into secondary channel 11722 but can self-retract via the edge feature 1143. Likewise, the secondary latch pin 1145 can project into the primary channel 11701 but can self-retract via the edge feature 1144. It can be said that the primary latch pin assembly 1140 can be configured to project into the valve side arm 1112 within a reset zone. The reset zone can be a second distance greater than the first distance D1. This second distance can be a subset of distance D2. Channel edge 31722 on the valve side arm 1112 can be configured to act on an edge feature 1143 on the primary latch pin assembly to retract the primary latch pin 1140 into the cam side latch bore comprising primary channel 11701. Likewise, secondary latch pin 1145 can be configured to project into cam side arm 1114 within a reset zone. This reset zone can likewise be a distance that is a subset of distance D2. So, the latch pin assembly can retract by the forces of rotation of the rocker arm assembly.
On the first end 11541 of secondary latch pin 1142, one or more additional edge features 1145 can be included for light weighting, alleviating strain, or improving oil pressure control.
Turning to
Other implementations will be apparent to those skilled in the art. The foregoing description is not intended to be exhaustive. Individual elements or features of a particular example are not exclusive to that particular example, but, where applicable, are interchangeable and can be used in other examples disclosed. For example the retracting features of
This application is a bypass continuation in part of, and claims priority to, Patent Cooperation Treaty application PCT/EP2019/025261 filed Aug. 7, 2019, which claims the benefit of priority of U.S. provisional patent application Ser. No. 62/716,712 filed Aug. 9, 2018. The priority documents are incorporated herein by reference in their entirety.
Number | Date | Country | |
---|---|---|---|
62716712 | Aug 2018 | US |
Number | Date | Country | |
---|---|---|---|
Parent | PCT/EP2019/025261 | Aug 2019 | US |
Child | 17018008 | US |