OIL COOLING FOR ELECTROMAGNETIC LATCH HOUSED IN ROCKER ARM

Abstract

A valvetrain includes a rocker arm assembly basing a rocker arm and an electromagnetic latch assembly. An electromagnet of the latch assembly is housed within a chamber formed by the rocker arm. Passageways suitable for oil cooling of the electromagnet are formed through and inside the rocker arm. In some embodiments, oil for cooling is supplied through a pivot. In some embodiments, oil for cooling is obtained from oil splash. Oil cooling may allow modes of operation such as of dynamic cylinder deactivation and dynamic variable valve actuation to be used without overheating the electromagnet.

Claims

1-15. (canceled)

16. A valvetrain for an internal combustion engine of a type that has a combustion chamber, a moveable valve having a seat formed in the combustion chamber, and a camshaft, comprising: a rocker arm assembly comprising a rocker arm that forms a chamber having edges and a cam follower configured to engage a cam mounted on a camshaft as the camshaft rotates; a housing inside the chamber; an electromagnetic latch assembly comprising an electromagnet inside the housing and a latch pin translatable between a first position and a second position; and oil passages in a space between the housing and the edges of the chamber.

17. The valvetrain of claim 16, wherein the oil passages are formed by channels in either an inward facing surface of the chamber or an outward facing surface of the housing.

18. The valvetrain of claim 16, wherein the chamber is a retrofit hydraulic chamber.

19. The valvetrain of claim 16, wherein the oil passages communicate with an opening onto a surface of the rocker arm that has a gothic profile.

20. The valvetrain of claim 16, further comprising: a pivot that provides a fulcrum for the rocker arm assembly; wherein the oil passages communicate with an opening on a surface of the rocker arm that interfaces with the pivot.

21. The valvetrain of claim 20, wherein oil flow from the pivot the space between the housing and the edges of the chamber restricted by one of the oil passages having a diameter of 2 mm or less.

22. The valvetrain of claim 20, wherein: the pivot has an oil passage; the cam has a cam cycle through which the cam periodically lifts the rocker arm; an opening of the oil passage in the pivot communicates with the opening on the surface of the rocker arm during one part of the cam cycle; and the opening of the oil passage in the pivot does not communicate substantially with the opening in the surface of the rocker arm during another part of the cam cycle.

23. The valvetrain of claim 20, wherein: the pivot has an oil passage; and an opening of the oil passage in the pivot communicates with the opening in the surface of the rocker arm only when the rocker arm is being lifted by the cam.

24. A method of operating the valvetrain of claim 16, the method comprising: generating heat inside the rocker arm by operating the electromagnet; and removing a majority of the heat with a flow of oil through the oil passages.

25. A valvetrain for an internal combustion engine of a type that has a combustion chamber, a moveable valve having a seat formed in the combustion chamber, and a camshaft, comprising: a rocker arm assembly comprising a rocker arm that forms a chamber having edges and a cam follower configured to engage a cam mounted on a camshaft as the camshaft rotates; a housing inside the chamber; and an electromagnetic latch assembly comprising an electromagnet inside the housing and a latch pin translatable between a first position and a second position; wherein the housing has ports that allow oil to flow into and out of the chamber.

26. A method of operating the valvetrain of claim 25, the method comprising: generating heat inside the rocker arm by operating the electromagnet; and removing a majority of the heat with a flow of oil through the housing.

27. The valvetrain of claim 25, wherein the chamber is a retrofit hydraulic chamber.

28. The valvetrain of claim 25, wherein one of the ports communicates with an opening onto a surface of the rocker arm that has a gothic profile.

29. The valvetrain of claim 28, wherein the communication between the opening and the port is restricted by a passage having a diameter of 2 mm or less.

30. The valvetrain of claim 28, further comprising: a pivot that provides a fulcrum for the rocker arm assembly; wherein one of the ports communicates with an opening on a surface of the rocker arm that interfaces with the pivot.

31. The valvetrain of claim 30, wherein: the pivot has an oil passage; the cam has a cam cycle through which the cam periodically lifts the rocker arm; an opening of the oil passage in the pivot communicates with the opening on the surface of the rocker arm during one part of the cam cycle; and the opening of the oil passage in the pivot does not communicate substantially with the opening in the surface of the rocker arm during another part of the cam cycle.

32. The valvetrain of claim 30, wherein: the pivot has an oil passage; and an opening of the oil passage in the pivot communicates with the opening in the surface of the rocker arm only when the rocker arm is being lifted by the cam.

33. A valvetrain for an internal combustion engine of a type that has a combustion chamber, a moveable valve having a seat formed in the combustion chamber, and a camshaft, comprising: a rocker arm assembly comprising a rocker arm that forms a chamber having edges and a cam follower configured to engage a cam mounted on a camshaft as the camshaft rotates; an electromagnetic latch assembly comprising an electromagnet and a latch pin translatable between a first position and a second position; a first passage from an upper surface of the rocker arm into the chamber that allows oil splash to flow into the chamber; and a second passage in the rocker arm that allows the oil splash to flow out of the chamber.

34. The valvetrain of claim 33, further comprising a retention area formed on an outer surface of the rocker arm that directs oil toward the opening.

35. A method of operating the valvetrain of claim 33, the method comprising: generating heat inside the rocker arm by operating the electromagnet; and removing a majority of the heat with the oil splash.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0016] FIG. 1 is a cross-sectional side view of a portion of a rocker arm assembly according to some aspects of the present teachings.

[0017] FIG. 2 is a perspective view of a portion of a valvetrain that include two of the rocker arm assemblies illustrated in FIG. 1.

[0018] FIG. 3 provides a perspective view with some components removed of an engine including the valvetrain illustrated by FIG. 2.

[0019] FIG. 4 is a perspective view of some of the oil passages in a rocker arm according to the present teachings.

[0020] FIG. 5 provides a cutaway view of a hydraulic lash adjuster that may be used in the present teachings.

[0021] FIG. 6 is a top view showing a portion of a rocker arm according to the present teachings.

[0022] FIG. 7 is a cutaway view showing a portion of the rocker arm of FIG. 6.

[0023] FIG. 8 is a flow chart of a method of operating a valvetrain according to some aspects of the present teachings.

DETAILED DESCRIPTION

[0024] In the drawings, some reference characters consist of a number with a letter suffix. In this description and the claims that follow, a reference character consisting of that same number without a letter suffix is equivalent to a listing of all reference characters used in the drawings and consisting of that same number with a letter suffix. For example, “rocker arm 103” is the same as “rocker arm 103A, 103B, 103C”.

[0025] FIGS. 1-3 illustrate an internal combustion engine 102 including a valvetrain 104 and rocker arm assemblies 106. FIG. 1 is a cutaway view of a rocker arm assembly 106. Rocker arm assembly 106 includes an outer arm 103A, an inner arm 103B, a cam follower 111, and an electromagnetic latch assembly 122. FIG. 2 is a perspective of a portion of valvetrain 104 including two rocker arm assemblies 106 and a power transfer module 241 that provides power to electromagnetic latch assemblies 122. FIG. 3 illustrates portions of valvetrain 104 installed on the cylinder head 154 of engine 102. Additional parts of valvetrain 104 include poppet valves 152 (a type of moveable valve), a camshaft (not shown) on which are mounted cams (not shown), and pivots 140. Cam followers 111 are configured to engage and follow cams on the camshaft as the camshaft rotates.

[0026] With reference to FIG. 1, electromagnetic latch assembly 122 includes a latch pin 117 translatable between extended and retracted positions. FIG. 1 shows latch pin 117 in the extended position. In the extended position, outer arm 103A and inner arm 1036 are engaged by latch pin 117. In the retracted position, outer arm 103A and inner arm 103B are disengaged and inner arm 103B may be actuated by a cam without moving outer arm 103A. Pivot 140 sits within a bore formed in cylinder head 154 and provides a fulcrum for rocker arm assembly 106. Poppet valve 152 has a seat within cylinder head 154.

[0027] Outer arm 103A includes a gothic 172, which is a surface having a gothic profile. Gothic 172 is shaped to interface with pivot 140, whereby pivot 140 provides a fulcrum on which rocker arm assembly 106 pivots when latch pin 117 is in the engaging position and outer arm 103A is being lifted by a cam through cam follower 111.

[0028] Electromagnetic latch assembly 122 includes an electromagnet 119 formed by a coil of wire that may be wound about bobbin 167. Electromagnet 119 acts on ferrule 123, which is formed of ferromagnetic material. The magnetic force on ferrule 123 is transferred to latch pin 117 through core 118, which is paramagnetic.

[0029] Electromagnetic latch assembly 122 also includes permanent magnets 120A and 120B, which are arranged with confronting polarities and are operative to stably maintain latch pin 117 in both extend and retracted position. Permanent magnets 120 remain in fixed positions relative to electromagnet 119 and outer arm 103A even as latch pin 117 translates between extended and retracted positions. Permanent magnets 120 operate through magnet circuits formed in part by a pole piece 116 positioned between magnets 120 and a housing 166 that encloses electromagnet 119. Housing 166 is formed of ferromagnetic material and includes two parts, a cup-shaped part 166A and a cap 166B. Parts of electromagnetic latch assembly 122 including housing 166 are installed within a chamber 110 formed in outer arm 103A. Providing electromagnetic latch assembly 122 with dual positional allows electromagnetic latch assembly 122 with only intermittent power. If electromagnet 119 were powered continuously, it would be more susceptible to overheating.

[0030] Passages for oil cooling of electromagnet 119 are formed through and inside rocker arm 103A. These include a space 168 between housing 166 and the limits of chamber 110. In the illustrated example, space 168 in is formed by giving housing 166 an inward bow. Space 168 may alternatively be formed in any suitable manner, including for example enlarging chamber 110 above what is required to accommodate housing 166 or by forming channels in housing 166 or the edges of chamber 110. The space 168 is not required.

[0031] Passages for oil cooling of electromagnet 119 may also include openings 169A and 169B in housing 166, which allow oil to flow in and out of a space 170 within housing 166 surrounding and adjacent to electromagnet 119. The shape of passages formed by openings 169 and space 170 are illustrated in FIG. 4.

[0032] With reference to FIG. 1, passages for oil cooling of electromagnet 119 may also include passage 171, which extends from an opening 173 on gothic 172 to chamber 110. Passage 171 is offset from passage 174, which is a drain that facilitates free movement of latch pin 117. Passage 171 may convey a supply of oil from pivot 140 for cooling electromagnet 119.

[0033] FIG. 5 illustrates a pivot 140 suitable for providing oil for cooling electromagnet 119 through gothic 172. Pivot 140 may be a hydraulic lash adjuster with an oil feed 128 for lash adjustment and an oil feed 146 for supplying oil to the rocker arm assembly 106. Pivot 140 has an end 149 that provides a fulcrum for rocker arm assembly 106 and has a shape that mates with gothic 172. End 149 has an opening 150. Pivot 140 has an inner sleeve 145, an outer sleeve 143, and internal passages 148 providing communication between oil feed 128 and opening 150 in end 149.

[0034] The interface between end 149 and gothic 172 may be substantially oil tight and provide communication between opening 173 in outer arm 103A and opening 150 in pivot 140. This communication may be continuous or may depend on the pivot angle of outer arm 103A on pivot 140. For example, opening 173 may be positioned such that opening 150 communicates with opening 172 only when outer arm 103A is being lifted by a cam. A substantial degree of communication is one that permits oil to flow in amounts that are effective for cooling. An amount effective for cooling is generally at least 0.005 liters per minute.

[0035] Pivot 140 may provide oil to outer arm 103A at a pressure in the range from 35 to 45 psi. To provide adequate cooling without placing excessive demands on an oil pump, it is desirable to provide outer arm 103A with cooling oil at a flow rate in the range from 0.005 to 0.06 liters per minute. Adequate cooling keeps electromagnet 119 at a temperature of 200° C. or less. Given the supply pressure and the physical properties of the oil, the flow rate of the oil will be determined by the friction factor of the passages by which the oil flows through outer arm 103A. The flow rate of oil may be limited by making passage 171 sufficiently narrow that it accounts for most of the friction factor. A sufficiently narrow passage will generally be 2 mm or less in diameter. Typically, passage 171 will be 1 mm or less in diameter. For example, passage 171 may be 0.8 mm in diameter.

[0036] FIGS. 6 and 7 illustrate an outer arm 103C that may be used in place of outer arm 103A to provide oil cooling of electromagnet 119 using oil splash in the environment around rocker arm assembly 106. Rocker arm 103C has an opening 182 formed in its upper surface to allow oil to enter outer arm 103C. Another opening (not shown may be formed at the bottom of outer arm 103C to allow the oil to drain out. Hole 182 may have a chamfered edge 180 to facilitate the admission of oil. A dam 184, which is a raised structure on the outer surface of outer arm 103C, may be positioned to direct oil splash toward opening 182. Dam 184 has a concave surface 183 to moving oil toward opening 182. Frame 181, which is a structure provided on outer arm 103C that provides electrical connections for powering electromagnet 119, may also provide a dam that directs oil splash toward hole 182. Frame 181 and dam 184 form a retention area that directs oil toward hole 182

[0037] Electromagnetic latch assembly 122 provides both extended and retracted positions in which latch pin 117 is stable. As a consequence, either the latched or unlatched configuration can be reliably maintained without electromagnet 119 being powered. Positional stability refers to the tendency of latch pin 117 to remain in and return to a particular position. Stability is provided by restorative forces that act against small perturbations of latch pin 117 from a stable position. In electromagnetic latch assembly 122, stabilizing forces are provided by permanent magnets 120.

[0038] In accordance with some aspects of the present teachings, electromagnet 119 is powered by circuitry (not shown) that allows the polarity of a voltage applied to electromagnet 119 to be reversed. A conventional solenoid switch forms a magnetic circuit that include an air gap, a spring that tends to enlarge the air gap, and an armature moveable to reduce the air gap. Moving the armature to reduce the air gap reduces the magnetic reluctance of that circuit. As a consequence, energizing a conventional solenoid switch causes the armature to move in the direction that reduces the air gap regardless of the direction of the current through the solenoid's coil or the polarity of the resulting magnetic field. Latch pin 117 of electromagnetic latch assembly 122, however, may be moved in either one direction or another depending on the polarity of the magnetic field generated by electromagnet 119. Circuitry, an H-bridge for example, that allows the polarity of the applied voltage to be reversed enables the operation of electromagnetic latch assembly 122 for actuating latch pin 117 to either an extended or a retracted position.

[0039] FIG. 8 provides a flow chart of a method 200 according to some aspects of the present teachings that may be used to operate valvetrain 104 in engine 102. Method 200 begins with action 201, operating electromagnet 119 in a manner that generates heat inside rocker arm 103. That manner may include a duty cycle of at least 5%, optionally 20% or more. That manner may meet the requirements of dynamic cylinder deactivation or dynamic variable valve actuation. That manner may be one that would generate so much heat that electromagnet 119 would heat to an excessive temperature, such as a temperature greater than 200° C., absent oil cooling.

[0040] Method 200 continues with act 203, flowing oil through the rocker arm 103 to remove heat. In some embodiments, the oil flow is provided through a pivot that provides a fulcrum for rocker arm assembly 106. In some embodiments, the oil is provided by oil splash. In some embodiments, the oil has a flow rate through rocker arm 103 that remains in the range from 0.005 to 0.06 liters per minute over a significant period, such as a period sufficient to prevent a temperature excursion over 200° C. In some embodiments, the oil removes a majority of the heat generated by operating the electromagnet 119. In some of these teaching, the oil flow rate is sufficient to keep electromagnet 119 at a temperature of 190° C. or less.

[0041] The components and features of the present disclosure have been shown and/or described in terms of certain teachings and examples. While a particular component or feature, or a broad or narrow formulation of that component or feature, may have been described in relation to only some aspects of the present teachings or some examples, all components and features in either their broad or narrow formulations may be combined with other components or features to the extent such combinations would be recognized as logical by one of ordinary skill in the art.