Electromagnetic actuator for operating a cylinder valve of an internal combustion engine

Information

  • Patent Grant
  • 6502534
  • Patent Number
    6,502,534
  • Date Filed
    Monday, April 16, 2001
    23 years ago
  • Date Issued
    Tuesday, January 7, 2003
    21 years ago
Abstract
An electromagnetic actuator for operating a cylinder valve in an internal combustion engine includes first and second housings secured to one another. Each housing has a cavity and a through bore extending therefrom. First and second electromagnets are disposed in the cavity of the respective housings. Each electromagnet has a yoke, a coil and a pole face. The pole faces are oriented toward and spaced from one another, and a reciprocating armature is disposed between the pole faces. A spring which urges the armature away from the first electromagnet has an end oriented away from the armature. A support cap is axially insertable in the through bore of the first electromagnet and includes a cap base having an inner face supporting the spring end. A locking arrangement secures the support cap to the housing and has a component axially insertable in the through bore with the support cap.
Description




CROSS REFERENCE TO RELATED APPLICATION




This application claims the priority of German Application No. 100 18 739.0 filed Apr. 15, 2000, which is incorporated herein by reference.




BACKGROUND OF THE INVENTION




An electromagnetic actuator for operating a cylinder valve of a piston-type internal-combustion engine has to be mass produced in large numbers in an economical manner. Such an electromagnetic actuator includes opening and closing electromagnets having spaced, facing pole faces, an armature reciprocated between the pole faces and coupled to the cylinder valve to move the latter into open and closed positions, as well as opening and closing (resetting) springs opposing the armature motion.




German Offenlegungsschrift (application published without examination) 198 25 728 discloses an electromagnetic actuator of the above-outlined type. The electromagnets are each provided with a respective, separate housing for receiving the magnet yoke which supports a coil. Such housings make possible a mass produced assembly of complete electromagnetic actuators. The housings are expediently made of a non-magnetic metal, for example, aluminum or an aluminum alloy so that they may be mass produced with a suitable casting process (such as die casting) in large numbers in an economical manner and adapted to individual requirements. On its side oriented away from the pole face of the inserted yoke body, the housing is provided with a tubular passage for receiving one end of a resetting spring. Thus, each housing may be used either for the part serving the opening function or the part serving the closing function.




In the housing oriented towards the cylinder valve the closing spring extends through the housing passage and is supported at its ends by the engine block and, respectively, by a spring seat disk affixed to the cylinder valve stem.




In the housing oriented away from the cylinder valve the opening spring passes through the housing passage and is supported on a threaded sleeve, by means of which the mid position of the armature between the pole faces of the two electromagnets may be adjusted. Such a threaded sleeve involves not only high manufacturing and assembly costs but also has disadvantages as concerns the reproducibility of an optimal setting and its handling during maintenance work.




SUMMARY OF THE INVENTION




It is an object of the invention to provide an improved electromagnetic actuator of the above-outlined type from which the discussed disadvantages are eliminated.




This object and others to become apparent as the specification progresses, are accomplished by the invention, according to which, briefly stated, the electromagnetic actuator for operating a cylinder valve in an internal combustion engine includes first and second housings secured to one another. Each housing has a cavity and a through bore extending therefrom. First and second electromagnets are disposed in the cavity of the respective housings. Each electromagnet has a yoke, a coil and a pole face. The pole faces are oriented toward and spaced from one another, and a reciprocating armature is disposed between the pole faces. A spring which urges the armature away from the first electromagnet has an end oriented away from the armature. A support cap is axially insertable in the through bore of the first electromagnet and includes a cap base having an inner face supporting the spring end. A locking arrangement secures the support cap to the housing and has a component axially insertable in the through bore with the support cap.




By eliminating the conventional, disadvantageous threaded sleeve, both actuator housings may be made from identical blanks without major finishing costs. By using an axially insertable support cap including a plug-in lock, cutting threads into the housing for a threaded adjusting sleeve cooperating with the opening spring is no longer needed. Merely geometrical elements for a plug-in lock are needed which may be readily formed in the housing blank. The presence of such housing configuration is harmless for the other, cap-less housing (accommodating the opening magnet) because, as concerns the opening magnet, only the closing spring is received in the housing passage and therefore any particular housing shape required for the support cap does not cause disturbance during service. Plug-in support bodies may be installed in a simple manner and further have the advantage that they may be made in large numbers of shaped steel sheet. Making the support cap from steel sheet also has the advantage that the cap, although exposed to high tension forces, may be relatively thin-walled. A further advantage compared to a conventional thread provided in the actuator housing resides in the fact that the securing and locking means can be made as large-area members so that the securing means of the steel supporting cap and the housing (such as an aluminum casting) may engage one another with a low surface pressure.




According to a preferred embodiment of the invention, in the region of the through bore the support cap and the housing together form the support cap lock which immobilizes the support cap in the actuator housing. This is achieved by configuring the lock as a bayonet lock composed of at least one radial projection and a receiving element for accommodating the projection, provided, for example, on the outer surface of the support cap and the housing, respectively. Upon assembly, the support cap may be plugged into the housing passage (through bore) and is thereafter rotated about its axis to lock it in place.




According to a particularly advantageous feature of the invention the projection and/or the projection receiving element is configured as a helical ramp in relation to the longitudinal actuator axis. As a result, by rotating the support cap relative to the housing, the bias of the opening spring may be changed and thus the mid position of the armature between the two pole faces may be adjusted. According to the invention, securing means are provided for fixing the support cap in the housing in a predeterminable position of installation.




According to a further advantageous feature of the invention, the outer surface of the cap base whose inner bottom surface is engaged by the opening spring is provided with at least one element for receiving a mounting tool. Such an element may be a rectangular opening provided in the cap base or two openings radially spaced from the central axis of the supporting cap to receive, respectively, a quadrilateral wrench or a hook wrench. After inserting the supporting cap into the housing bore while compressing the opening spring, the support cap may be turned into its locked position by the wrench inserted into the receiving element.




In accordance with a further advantageous feature of the invention, at least the base of the support cap made of steel sheet is tempered (hardened). The opening spring engages at one end a spring seat disk which is made of a wear resistant material and which is affixed to an armature guide bar. The other end of the opening spring engages the inner surface of the cap base. Since at that location substantial spring forces have to be taken up and the support of the springs in operation is exposed to a fluctuating pressing load, a hardened cap base prevents the spring end from working itself into the cap material.




Instead of providing a helical ramp for the projection and/or the projection-receiving element of the bayonet lock for the support cap, according to another feature of the invention at least one adjusting washer is positioned on the inner face of the cap base for engaging the opening spring. By inserting adjusting washers of different thicknesses or as a stack, it is possible to adjust, within the required accuracy, the mid position of the armature between the two pole faces. By virtue of this measure the structure of the lock between the support cap and the housing is simplified since the support cap needs only to be inserted into the housing bore and then locked to the housing by rotation.











BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is an axial sectional view of an electromagnetic cylinder valve actuator incorporating the invention.





FIG. 2

is a perspective view of a housing for the closing magnet of the actuator, provided with a support cap for the opening spring according to a preferred embodiment of the invention.





FIG. 3

shows the magnet housing of

FIG. 2

without the support cap.





FIG. 4

is a sectional view taken along line IV—IV of FIG.


3


.





FIG. 5

is a perspective view of the support cap shown in FIG.


2


.





FIG. 6

is a sectional view taken along line VI—VI of FIG.


5


.





FIG. 7

is a sectional elevational view of a support cap according to a variant of the

FIG. 6

structure.





FIG. 8

is a perspective view of another preferred embodiment of the invention.





FIG. 9

is a sectional view taken along line IX—IX of FIG.


8


.





FIG. 10

is a perspective view of a support cap according to the embodiment shown in FIG.


8


.





FIG. 11

is a perspective view of another preferred embodiment of the support cap for use in a housing shown in FIG.


8


.











DESCRIPTION OF THE PREFERRED EMBODIMENTS




The electromagnetic actuator illustrated in

FIG. 1

includes a closing electromagnet


1


and an opening electromagnet


2


. The magnets


1


,


2


which are separated from one another by spacer members


3


.


1


and


3


.


2


have respective pole faces


4


oriented toward one another. In the space between the two pole faces


4


an armature


5


is movable from one pole face to the other and is attached to a guide bar


6


passing through the electromagnet


2


. In the illustrated embodiment the armature


5


has a rectangular outline.




A further guide bar


7


passes through the electromagnet


1


in aligned contact with the guide bar


6


. At its upper end


7


′ the guide bar


7


is connected with a resetting spring


8


which serves as an opening spring. The lower free end


9


of the guide bar


6


engages the upper free end


10


of the valve stem


11


of a valve which is guided in an only symbolically shown cylinder head


12


of an internal combustion engine. By means of a resetting spring


13


which serves as a closing spring, the cylinder valve is urged in the closing direction. The closing spring


13


and the opening spring


8


exert their spring force in facing, opposite directions whereby in the de-energized state of the electromagnets


1


and


2


the armature


5


assumes its position of rest in the mid region between the two pole faces


4


of the electromagnets


1


and


2


, as illustrated in FIG.


1


.




In case the two electromagnets


1


and


2


are alternatingly energized, the armature


5


alternatingly arrives at the respective pole face


4


of the two electromagnets


1


and


2


and, accordingly, the cylinder valve is, for the duration of the energization, maintained in the open position (engagement of the armature


5


with the pole face


4


of the electromagnet


2


) against the force of the closing spring


13


or in the closed position (engagement of the armature


5


with the pole face


4


of the electromagnet


1


) against the force of the opening spring


8


.




The electromagnetic actuator illustrated in

FIG. 1

is a structural unit composed of practically identical modular elements. The two electromagnets are preferably of identical construction and are each composed essentially of a separate housing


14


which has a cavity


15


oriented towards the armature


5


for receiving a yoke body


16


carrying a coil


17


. The housing


14


further has a through bore


18


through which the respective opening spring


8


or closing spring


13


may partially pass.




As indicated by the flatness of the actuator housing


14


shown in

FIG. 2

, the electromagnetic actuator is of very narrow construction allowing a close, side-by-side installation of such actuators in the limited space of the engine. The yoke body


16


is, together with the coil


17


, inserted into the cavity


15


of the housing


14


and is fixed and held therein by means of a suitable cast mass.




The housing


14


further has an additional lateral opening


20


which permits access to the terminals


21


of the coil


17


. By virtue of such an arrangement the two electromagnets


1


,


2


may be connected to the actuator control by a coded, one-piece plug


22


(shown in dash-dot lines) in a non-interchangeable manner. The plug


22


is positioned and protected in the lateral flanks of the lateral opening


20


.




Reverting to

FIG. 1

, the two housings


14


made, for example, of an aluminum alloy by means of die casting, have aligned passages


23


which extend parallel to the axis of the guide bars


6


and


7


and cooperate with similar apertures provided in spacers


3


.


1


and


3


.


2


positioned between the two housings


14


. The two housings


14


may thus be firmly bolted to one another and/or to the engine block


12


with the interposition of the spacers


3


.


1


and


3


.


2


.




The opening spring


8


is supported by a support cap


25


serving as a spring-force setting element. By turning the support cap


25


or by inserting adjusting washers, the mid position of the armature


5


between the two pole faces


4


may be altered.




As may be seen in FIG.


1


and particularly in

FIG. 2

, the through bore


18


is surrounded by a flange


19


at its end oriented away from the yoke body


16


. Also referring to

FIG. 3

, on the inside the through bore


18


is, on diametrically opposite sides, provided with groove-like recesses


26


cooperating with respective, radially outwardly oriented projections


27


provided on the support cap


25


, as also shown in

FIGS. 5

,


6


and


7


. By virtue of this structure the support cap


25


may be inserted axially into the through bore


18


and then rotated to be immobilized in the housing


14


by a bayonet-type lock. Upon insertion of the support cap


25


, the opening spring


8


, previously positioned on a spring seat disk


7


″ affixed to the upper end


7


′ of the guide bar


7


, is compressed. By virtue of the bias of the opening spring


8


the support cap


25


is held in its position even when the armature


5


is in engagement with the pole face


4


of the opening magnet


2


.




The base


28


of the support cap


25


is provided with a polygonal (for example, rectangular, as shown in

FIG. 2

) aperture


29


for receiving a non-illustrated turning tool to rotate the support cap


25


after it has been inserted into the through bore


18


.




In actuator constructions in which the upper end of the guide rod


7


passes through the opening spring


8


and through the base


28


of the support cap


25


and is provided with sensor elements, the through aperture


29


is circular. In such a case, as illustrated in

FIG. 5

, as tool receptors spaced bore holes


29


.


1


are provided into which a suitable hook wrench may be inserted for turning the support cap


25


.




The embodiment illustrated in

FIG. 2

is shown in detail in

FIGS. 4 and 5

and will be further described as the specification progresses.




As may observed in

FIG. 4

, adjacent the groove like recesses


26


the lower edge


30


of the through bore


18


has an undercut which is configured as a helical ramp


31


provided with a plurality of consecutive depressions.




Correspondingly, as seen in

FIG. 5

, the projections


27


have nose-like elevations


32


which may be brought into engagement with the depressions on the ramp


31


by rotating the support cap


25


in the through bore


18


. By virtue of the slope of the ramp


31


the distance of the cap base


28


changes relative to the pole face


4


of the closing magnet


1


in the shortening direction if, after insertion of the support cap


25


the latter is turned clockwise. As a result, the bias of the opening spring


8


is increased and, accordingly, the armature


5


is shifted in the direction of the pole face


4


of the opening magnet


2


, simultaneously compressing the closing spring


13


. By virtue of the engagement of the nose-shaped elevations


32


into the depressions on the ramp


31


, the support cap


25


is immobilized in the housing


14


and thus securely prevented from rotating.




Instead of depressions on the helical ramp


31


and corresponding nose-like elevations


32


on the support cap


25


, it is feasible to configure the ramp


31


as well as the projection


27


to have a smooth surface as shown in FIG.


7


. The angular immobilization of the support cap


25


after adjustment of the mid position of the armature


5


may be effected by a plug-in pin which passes through radial bores


33


in the support cap and corresponding, non-illustrated radial holding bores in the housing flange


19


. It is also feasible, however, to provide the edge


27


.


1


of the projections


27


with a series of tooth-like recesses associated with at least one holding bore passing axially parallel through the flange


19


. Thus, after setting the mid position of the armature by turning the support cap


25


in the appropriate angular position, the support cap


25


may be angularly immobilized by a pin passing through the holding bore in the flange


19


and a corresponding, axially parallel bore in the edge


27


.


1


of the projection


27


.





FIG. 8

is a perspective view of an embodiment in which the housing is provided with partial collar-like elevations


19


.


1


on its side oriented away from the housing cavity for the yoke body. As shown in

FIG. 9

, radial holding pins


34


pass through the elevations


19


.


1


and project into corresponding recesses


35


provided in the circumferential wall of the support cap


25


. The recesses


35


may be through openings as shown in FIG.


10


. For loosening the support cap the pins


34


are removed.




As shown in the variant illustrated in

FIG. 11

, it is also feasible to provide, in the circumferential wall of the support cap


25


, a slit-like recess


36


having an approximately L-shaped course and terminating in a detent


37


. Such a support cap may be inserted on the pins


34


affixed to the collar-like insert


19


.


1


and may be immobilized by rotation. Here too, the support cap


25


is held in its position by the bias of the opening spring


8


.




In the embodiment according to

FIGS. 9

,


10


and


11


but also in all the previously described embodiments when suitably modified, the adjustment of the mid position of the armature


5


is effected by inserting and positioning on the base


28


of the support cap


25


one or more washers


38


of predetermined thickness before attaching the support cap


25


to the housing


14


.




The adjusting washers


38


may also be used when for the adjustment of the mid position of the armature


5


only an insufficient setting path is available for the projection


27


on the helical ramp


31


.




The wall thicknesses available for the housing


14


are sufficient to take up fluctuating stresses even if made of aluminum or aluminum die cast. The support cap


25


which should be thin-walled, is expediently made of steel sheet; for increasing the wear resistance, at least the base


28


is tempered to prevent the end of the opening spring from working itself into the base


28


during operation. Despite the thinness of the walls, the fluctuating spring forces acting between the housing


14


and the support cap


25


may be taken up as tension stresses via the steel plate material of the support cap


25


.




The drawings readily show that the arrangement of projections and projection-receiving elements may be interchanged, that is, the through bore


18


, instead of the groove-like receiving elements


26


, may be provided with the radial projections


27


and, likewise, the support cap


25


, instead of the projections, may be provided with the groove-like receptors.




It will be understood that the above description of the present invention is susceptible to various modifications, changes and adaptations, and the same are intended to be comprehended within the meaning and range of equivalents of the appended claims.



Claims
  • 1. An electromagnetic actuator for operating a cylinder valve in an internal combustion engine; the actuator having a longitudinal axis and comprising(a) first and second housings secured to one another; each housing having a cavity and a through bore extending from said cavity; (b) first and second electromagnets disposed in said cavity of respective said first and second housings; each said electromagnet having a yoke, a coil carried by said yoke and a pole face; the pole faces of said electromagnets being oriented toward and spaced from one another; (c) an armature disposed between said pole faces for an axial reciprocation therebetween upon energization of said first and second electromagnets; (d) a spring urging said armature away from said first electromagnet; said spring having an end oriented away from said armature; (e) a support cap axially insertable in said through bore of said first housing; said support cap including a cap base having an inner face supporting said spring at said end thereof; and (f) locking means for securing said support cap to said housing; said locking means having at least one radially outwardly oriented projection from a surface of said cap, at least one axially oriented grove-like recess which is formed in a housing wall of the first housing defining said through bore, for receiving said at least one projection, and a circumferentially oriented receiving part in said housing for receiving the projection from the recess upon rotation of the cap, whereby said locking means is a bayonet lock.
  • 2. The electromagnetic actuator as defined in claim 1, wherein at least one of said projection and said receiving part has a helically extending ramp related to said longitudinal axis and which is engaged by the other of said projection and said receiving part.
  • 3. The electromagnetic actuator as defined in claim 1, further comprising immobilizing means for fixing said support cap in a predetermined angular position relative to said housing.
  • 4. The electromagnetic actuator as defined in claim 1, wherein said cap base includes an element for receiving a mounting tool.
  • 5. The electromagnetic actuator as defined in claim 1, wherein said support cap is made of deformed steel sheet.
  • 6. The electromagnetic actuator as defined in claim 1, wherein said cap base is hardened.
  • 7. The electromagnetic actuator as defined in claim 1, further comprising an adjusting washer positioned on said inner face of said cap base.
  • 8. The electromagnetic actuator as defined in claim 2, wherein said projection and said receiving part have corresponding helically extending ramps related to said longitudinal axis.
  • 9. The electromagnetic actuator as defined in claim 8, further comprising immobilizing means for fixing said support cap in a predetermined angular position relative to said housing.
  • 10. The electromagnetic actuator as defined in claim 9, wherein said immobilizing means comprises a plurality of depressions formed in a surface of the ramp of one of said receiving part and said projection, and a plurality of corresponding protrusions formed in a surface of the other of the projection and said receiving part.
  • 11. The electromagnetic actuator as defined in claim 2, further comprising immobilizing means for fixing said support cap in a predetermined angular position relative to said housing.
  • 12. The electromagnetic actuator as defined in claim 11, further comprising an annular collar formed on an end surface of said first housing oriented away from the housing cavity for the yoke body and surrounding the through bore; and wherein said immobilizing means includes at least one recess in a circumferential surface of each of said cap and said collar, and a pin passing through said at least one recess in both said cap and said collar.
  • 13. An electromagnetic actuator for operating a cylinder valve in an internal combustion engine; the actuator having a longitudinal axis and comprising(a) first and second housings secured to one another; each housing having a cavity and a through bore extending from said cavity; (b) first and second electromagnets disposed in said cavity of respective said first and second housings; each said electromagnet having a yoke, a coil carried by said yoke and a pole face; the pole faces of said electromagnets being oriented toward and spaced from one another; (c) an armature disposed between said pole faces for an axial reciprocation therebetween upon energizing said first and second electromagnets; (d) a spring urging said armature away from said first electromagnet, with said spring having an end oriented away from said armature; (e) a support cap axially insertable in said through bore of said first housing, with said support cap including a cap base having an inner face supporting said spring at said end thereof; and (f) locking means for securing said support cap to said housing, with said locking means comprising collar-like elevations disposed on a surface of said first housing facing away from the cavity for the respective yoke body and about the respective through bore, corresponding recesses formed in a circumferential surfaces of said elevations and of said cap, and at least one pin disposed in a recess in one of said elevations and projecting into a recess in said cap.
  • 14. The electromagnetic actuator as defined in claim 13, wherein said at least one pin passes through the elevation and into the recess of the cap.
  • 15. The electromagnetic actuator as defined in claim 13, wherein said at least one recess in said cap is substantially L-shaped with one arm of the recess extending to an edge surface of said cap oriented toward the respective cavity of the housing.
  • 16. The electromagnetic actuator as defined in claim 13, wherein said cap base includes an element for receiving a mounting tool.
  • 17. The electromagnetic actuator as defined in claim 13, wherein said support cap is made of deformed steel sheet.
  • 18. The electromagnetic actuator as defined in claim 13, wherein said cap base is hardened.
  • 19. The electromagnetic actuator as defined in claim 13, further comprising an adjusting washer positioned on said inner face of said cap base.
Priority Claims (1)
Number Date Country Kind
100 18 739 Apr 2000 DE
US Referenced Citations (2)
Number Name Date Kind
6164253 Alberter et al. Dec 2000 A
6199843 DeGrace May 2001 B1