Arrangement for preventing bearing-related noise in internal combustion engines

Information

  • Patent Grant
  • 6550441
  • Patent Number
    6,550,441
  • Date Filed
    Thursday, November 15, 2001
    23 years ago
  • Date Issued
    Tuesday, April 22, 2003
    21 years ago
Abstract
Internal combustion engine with variable compression, comprising a crankshaft-bearing crankcase part and a cylinder-receiving part arranged tiltably thereon by means of a tilt axle bearing on one side of the engine and a tilt mechanism on the other, opposite side of the engine. The cylinder-receiving part supports a cylinder head which is securely connected thereto, preferably with camshafts mounted therein. There are prestressing members arranged between the crankcase part and the cylinder-receiving part which force these engine parts apart and work to counteract the occurrence of bearing play in the tilt axle bearing and in the tilt mechanism when compression-modifying tilting movement between the cylinder-receiving part and the crankcase part occurs during running of the engine.
Description




The present invention relates to an internal combustion engine having a crankcase part and a cylinder receiving part which are tiltably mounted with respect to each other and particularly relates to control of the tilting.




In this type of internal combustion engine, the compression can be varied by means of the fact that the engine's cylinder-receiving part (with associated cylinder head) can be tilted (inclined) to the side in relation to the crankcase part. To permit this, the cylinder-receiving part is mounted tiltably on the crankcase part on one side of the engine, and is connected movably to the crankcase part on the other, opposite side of the engine, by way of a tilt mechanism located there.




PRIOR ART




Internal combustion engines of the abovementioned type are already known, and in this connection reference may be made, for example, to U.S. Pat. No. 2,770,224 and SE-B-470 238.




The first of these patent specifications describes a piston engine with a fixed crankcase part, to which a cylinder-receiving engine part with associated cylinder cover is connected in an articulated manner. The combustion chamber volumes of the cylinders can be varied by tilting the cylinder-receiving engine part sideways about a longitudinal tilt axle. This tilting movement, i.e. change in the lateral inclination, is obtained by turning of an eccentric axle included in a tilt mechanism acting between the crankcase part and the cylinder-receiving engine part.




When the cylinder-receiving part (cylinder block) of an internal combustion engine, for example an in-line engine, of the abovementioned type is inclined (tilted) relative to the crankcase part, the distance between the crankshaft mounted in the crankcase part (with associated pistons linked to connecting rods) and the cylinders in the cylinder-receiving part changes. The volume of that part of the combustion chamber which lies above the respective piston's upper boundary surface (piston top) at the upper dead centre of the piston is thereby changed. The compression ratio of the engine can thus be varied in this way, and efficiency is thereby optimized for varying loading conditions. The performance of the engine and thus also of the vehicle in question is thereby improved.




OBJECT OF THE INVENTION




As a result of the above structural configuration of an internal combustion engine, and its principle of changing (varying) the compression in the cylinders by means of lateral tilting of the cylinder-receiving part in relation to the crankcase part of the engine, a certain amount of clearance or play arises both in the tilt axle bearing and in the various bearings of the tilt mechanism when the tilting movement in question takes place.




Since the tilt axle bearing on one side of the engine comprises a number of bearing lugs in the crankcase part, and a number of bearing lugs on the cylinder-receiving part which project into the spaces between these bearing lugs, and also a bearing axle passing through and connecting all these bearing lugs, it is necessary, for assembly technology reasons, to accept greater manufacturing tolerances, and thus greater bearing play, than it would be possible to achieve purely from the viewpoint of manufacturing technology.




This fact, together with the consideration that lubricant-free bearings ought in practice to be chosen —on account of small relative movements between interacting bearing components/bearing surfaces and the lack of sufficiently frequent changing of direction of force—means that the bearing play is quite great, thereby causing unwanted noise, especially at high loads.




The primary object of the present invention is to design an engine operating with variable compression in such a way that the occurrence of the abovementioned bearing-related noise can be prevented or at least to a large extent obviated.




DESCRIPTION OF THE INVENTION




According to the present invention, the above object is achieved by the fact that the engine has the features set out herein.




Thus, the primary distinguishing feature of the internal combustion engine is that, arranged between the crankcase part and the cylinder-receiving part there are prestressing members which force these engine parts apart and work to counteract the occurrence of bearing play in the tilt axle bearing and in the tilt mechanism when compression modifying tilting movement between the cylinder-receiving part and the crankcase part occurs during running of the engine.




Developments and preferred embodiments of the subject of the invention are also described.




Because the cylinder-receiving part with its associated cylinder head and the crankcase part are kept stressed apart in the manner indicated above, when the gas forces in the cylinders occur, the effect of the bearing play can be at least largely eliminated and the resulting noise in the engine can be prevented.




The internal combustion engine can, for example, be a four-cylinder, five-cylinder or six-cylinder in-line engine with overlying camshafts mounted in the cylinder head securely connected to the cylinder-receiving part. It is possible (but not essential) for the cylinder head and the cylinder-receiving part to be fully integrated and constitute parts of one and the same monobloc piece (monobloc engine).




On one side of the engine, the cylinder-receiving part has bearing lugs for the hinge axle of the tilt bearing, and on the opposite side of the engine bearing lugs for the upper hinge axle of the tilt mechanism. The last-mentioned bearing lugs preferably constitute integral parts of the cylinder-receiving part. Arranged between the crankcase part and the upper hinge axle of the tilt mechanism there are link members which transmit the tilting movement and which serve to change the distance between the said upper hinge axle and an eccentric shaft which is mounted in the bearing lugs of the crankcase part and which constitutes the lower hinge axle of the tilt mechanism.




In a first main embodiment according to the invention, the prestressing members are arranged inside the bearing lugs of the tilt axle bearing and are intended, with their opposite ends, to press directly or indirectly in one direction against a tilt axle passing through the bearing lugs and mounted in the crankcase part, and, in the other direction, to press against a collar part fixed in relation to the cylinder-receiving part.




In this embodiment, it is also preferable for the tilt mechanism members to comprise rods like connecting rods coupled between, on the one hand, a first axle which runs through the hearing lugs connected securely to the cylinder-receiving part and, on the other hand, a second axle mounted eccentrically in the crankcase part, prestressing members being arranged in the rods and being intended, with their opposite ends, to press directly or indirectly against the first axle and the second axle, respectively, in order to generate a force stressing these two axles apart.




On that side of the second axle remote from the rod (link member) transmitting the tilting movement, prestressing members are also preferably arranged in the crankcase part which act between the crankcase part and the associated side of the second axle and are intended to exert pressure on the axle.




The prestressing members in both the bearing lugs of the tilt axle bearing and in the rods (link members) and the crankcase part can preferably comprise cylindrical spring stacks consisting of cup springs.




In a second, alternative embodiment according to the invention, in the area between the tilt axle bearing and the tilt mechanism, and inserted between the crankcase part and the cylinder-receiving part, there are prestressing members which tension these two parts apart and act between, on the one hand, a collar part rigidly connected to the crankcase part and, on the other hand, a collar part rigidly connected to the cylinder-receiving part.




The collar part rigidly connected to the cylinder-receiving part can then be a tightening screw provided with a specially designed head and serving to fix a cylinder lining support on the underside of the cylinder-receiving part.




The collar part rigidly connected to the crankcase part can for its part, for example, consist of one end of a prestressing bar screwed into the crankcase part.




In the last-mentioned embodiment, the prestressing members can expediently be powerful cylindrical screw springs tensioned between the opposing collar parts in question.




In general terms, however, as regards the prestressing members according to the invention, these can either be suitable compression springs or spring stacks, or other types of force generators, for example hydraulic force generators.




When the engine is an in-line engine and the prestressing members are arranged as in the abovementioned second main embodiment, it is preferable, for reasons of force symmetry, for the prestressing members to be placed in an axial row and distributed uniformly along the cylinder line, preferably in the areas between adjacent cylinders in the cylinder line.











BRIEF DESCRIPTION OF THE FIGURES




The invention will now be explained and clarified with reference to a number of illustrative embodiments which are shown in the attached drawings.




In the drawings:





FIG. 1

shows a diagrammatic and perspective view of the main parts of the tilt mechanism in an internal combustion engine of the same basic type as the internal combustion engine according to the present invention;





FIG. 2

shows a partial diagrammatic side view of the tilt axle bearing in an embodiment of an internal combustion engine according to the invention;





FIG. 3

shows a diagrammatic cross section through the engine in

FIG. 2

; and





FIG. 4

shows a diagrammatic cross section through an alternative embodiment of an internal combustion engine according to the invention.











DESCRIPTION OF ILLUSTRATIVE EMBODIMENTS




The primary parts of an internal combustion engine of the type to which the present invention relates are shown in FIG.


1


. The internal combustion engine, in this case a four-cylinder in-line engine, is constructed in such a way that its compression can be varied while running. The engine comprises a crankcase part


2


, in which the crankshaft


4


(not shown here, but shown in

FIG. 4

) is mounted, and a cylinder-receiving part


6


which is connected tiltably to the crankcase part so that it can be inclined/tilted sideways in relation to the crankcase part. To permit this lateral tiltability of the cylinder-receiving part


6


, a tilt axle bearing


8


is provided between the parts


2


and


6


on the furthest away long side (not shown here) of the engine, and on the long side of the engine visible here there is a tilt mechanism, generally designated by 10, between the crankcase part


2


and the cylinder-receiving part


6


. The part


6


in this case contains four cylinders designated


12


, and a cylinder head


14


or cylinder cover (not shown here, but indicated diagrammatically in

FIG. 3

) is in a conventional manner intended to be sealingly secured on the flat top


16


of the part


6


.




The tilt axle bearing


8


not visible in

FIG. 1

comprises, in the same way as in the embodiment shown in

FIG. 2

, a number of bearing lugs


18


connected rigidly to the crankcase part


2


and a number of bearing lugs


20


which project upwards between these bearing lugs on the cylinder-receiving part


6


. Passing through these bearing lugs


18


,


20


there is a hinge axle


22


which thus couples the engine parts


2


and


6


in a hinged/tiltable manner. The number of bearing lugs of the parts


2


and


6


is of course dependent on the number of cylinders in the engine; note that the engine in

FIG. 1

has four cylinders, while the engine in

FIG. 2

has five cylinders.




The tilt mechanism


10


shown in

FIG. 1

comprises five bearing lugs


24


which are rigidly connected to the cylinder-receiving part


6


and form bearing brackets for an upper hinge axle


26


which runs through them and on which rods/links or connection members


28


are pivotably mounted, the lower ends of these being pivotably mounted on “crank-like” axle sections


30


of an eccentric axle


32


with larger bearing sections


34


rotatably mounted in bearing brackets of bearing lugs


36


of the crankcase part


2


. A rotation of the eccentric axle


32


generates a change in the distance between the upper hinge axle


26


and the axle sections


30


, and thus via the connection members


28


a sideways tilting/inclination of the cylinder-receiving part


6


in relation to the crankcase part


2


. The desired compression change in the cylinders is obtained in this way.




Reference is now made to the embodiment of the internal combustion engine according to the invention as shown in

FIGS. 2 and 3

. In order to prevent occurrence of noise related to bearing play during running of the engine, both in the tilt axle bearing


8


and in the tilt mechanism


10


, prestressing members


38


are arranged between the crankcase part


2


and the cylinder-receiving part


6


, which prestressing members


38


are in the form of powerful compression springs which by means of their inherent predetermined tensioning seek continually to press the engine parts


2


and


6


apart so that existing bearing play in the tilt axle bearing


8


and in the tilt mechanism


10


is eliminated in the direction generated by the action of the combustion gases in the cylinders. The pressure of the combustion gases in the combustion chambers in the cylinders seeks to threw the cylinder-receiving part


6


with associated cylinder head upwards, away from the crankcase part


2


.




Each of the prestressing members


39


designed as compression springs is inserted between, on the one hand, the end of an associated prestressing bar


40


screwed into the crankcase part


2


and, on the other hand, a collar part


42


rigidly connected to the cylinder-receiving part


6


. In this case, the collar parts


42


consist of the cup-shaped heads of fastening screws


44


which are still present at the appropriate sites and which are used for fastening a cylinder lining support


46


on the underside


48


of the cylinder-receiving part


6


.




Referring is finally made to the alternative embodiment of the internal combustion engine according to the invention as shown in FIG.


4


. The prestressing members between the crankcase part


2


and the cylinder-receiving part


6


are in this case positioned and designed differently from the design according to

FIGS. 2 and 3

.




Prestressing members


50


, here in the form of cylindrical cup springs, are in this case inserted in bores


52


inside bearing lugs


20


belonging to the cylinder-receiving part


6


of the tilt axle bearing


8


, where the prestressed members


50


exert pressure at the lower end against the hinge axle


22


and at the upper end against a collar part fixed in relation to the cylinder-receiving part


6


. Force transmission between the members


50


and the hinge axle


22


takes place via pressure blocks


54


with cylindrically concave sliding contact surface against the axle


22


. At the upper end of each prestressing member


50


, the force transmission to the engine part


6


takes place via a pressure rod


56


inserted into the bore


52


, which bar thus constitutes the collar part.




On the side of the engine with the tilt mechanism, there are two prestressing members


50


in and on each link-like connection member


28


. Inside each connection member


28


, there is a prestressing member


50


whose ends exert pressure on the upper hinge axle


26


and on the axle section


30


via pressure blocks


58


and


60


, respectively, with cylindrically concave sliding contact surfaces. Also arranged on the side of the eccentric shaft


32


remote from the connection members


28


, there are prestressing members


50


which each act between a part


62


rigidly connected to the crankcase part


2


and, on the other hand, the bearing section


34


of the eccentric shaft


32


. The contact with the bearing section


34


is via a pressure block


64


with cylindrically concave sliding contact surface.



Claims
  • 1. An internal combustion engine with variable compression, the engine comprising:a crankcase part through which a crankshaft may pass; a cylinder receiving part for receiving engine cylinders; a tilt axle bearing between the crankcase part and the cylinder receiving part, extending along the parts and connecting the parts to enable them to tilt relative to each other; a tilt mechanism between the crankcase part and the cylinder receiving part and located on the engine away from the tilt axle bearing and operable for tilting the parts with respect to each other around the tilt axle bearing; pre-stressing members between the crankcase part and the cylinder receiving part normally urging the crankcase part and the cylinder receiving part to tilt away from each other and to counteract any bearing play in the tilt axle bearing and in the tilt mechanism during running of the engine and during engine compression.
  • 2. The engine of claim 1, further comprising a cylinder head connected on the cylinder receiving part.
  • 3. The engine of claim 2, wherein the cylinder head and the cylinder receiving part are integral parts of a monobloc component.
  • 4. The engine of claim 1, wherein the engine has opposite lateral sides, the tilt axle bearing is toward one of the opposite lateral sides and the tilt mechanism is at at least in part toward the other of the opposite lateral sides.
  • 5. The engine of claim 4, wherein the cylinder receiving part has a plurality of cylinders therein, arranged along at least one row, and the one and opposite sides of the engine are on opposite sides of the at least one row of the cylinders.
  • 6. The engine of claim 1, wherein the tilt axle bearing comprises bearing lugs rigidly connected to the cylinder receiving part.
  • 7. The engine of claim 6, wherein the tilt axle bearing includes a tilt axle passing through the bearing lugs.
  • 8. The internal combustion engine of claim 6, wherein the mechanism comprises bearing lugs rigidly connected to the cylinder receiving part.
  • 9. The engine of claim 8, further comprising a collar fixed on the cylinder receiving part;the pre-stressing members being arranged inside the bearing lugs of the tilt axle bearing, the pre-stressing members having opposite first and second ends, and the first ends thereof pressing directly or indirectly in one direction against a tilt axle passing through the tilt axle bearing lugs, the tilt axle being disposed in the crankcase part and the second ends of the pre-stressing members pressing directly or indirectly in the other direction against the collar fixed to the cylinder receiving part.
  • 10. The engine of claim 9, further comprising a first axle running through the bearing lugs of and rigidly connected to the cylinder receiving part, a second axle mounted eccentrically in the crankcase part,the tilt members comprise connecting rods, the connecting rods being coupled between the first and second axles; the pre-stressing members being arranged in the rods and the opposite first and second ends of the pre-stressing members pressed directly or indirectly against the first and second axles respectively in order to generate a force which stresses the first and second axles apart.
  • 11. The engine of claim 10, wherein the second axle has a first side toward the rod and a second side remote from the rod; the pre-stressing members arranged in the crankcase part act between the crankcase part and the associated first side of the second axle for exerting pressure on the second axle.
  • 12. The internal combustion engine of claim 1, wherein the tilt mechanism comprises other bearing lugs rigidly connected to the cylinder receiving part.
  • 13. The engine of claim 12, wherein the tilt mechanism adjustable tilt members coupled between the crankcase part and the bearing lugs on the cylinder receiving part, the tilt members being so shaped and so connected with crankcase part and the bearing lugs on the cylinder receiving part, and operable to change the distance between the crankcase part and the bearing lugs on the cylinder receiving part for causing the tilting of the cylinder receiving part with respect to the crankcase part and thereby changing the compression ratio in the engine cylinder.
  • 14. The engine of claim 13, wherein the tilt members are so connected as to adjust their effective length to cause the tilting.
  • 15. The engine of claim 13, wherein the bearing lugs connected to the cylinder receiving part are integral parts thereof.
  • 16. The bearings of claim 12, further comprising a collar fixed on the cylinder receiving part;the pre-stressing members being arranged inside the bearing lugs of the tilt axle bearing, the pre-stressing members having opposite first and second ends, and the first ends thereof pressing directly or indirectly in one direction against the tilt axle passing through the bearing lugs, the tilt axle being disposed in the crankcase part and the second ends of the pre-stressing members pressing directly or indirectly in the other direction against the collar fixed to the cylinder receiving part.
  • 17. The engine of claim 16, further comprising a first axle running through the bearing lugs of and rigidly connected to the cylinder receiving part, a second axle mounted eccentrically in the crankcase part,the tilt members comprise connecting rods, the connecting rods being coupled between the first and second axles; the pre-stressing members being arranged in the rods and the opposite first and second ends of the pre-stressing members pressed directly or indirectly against the first and second axles respectively in order to generate a force which stresses the first and second axles apart.
  • 18. The engine of claim 1, wherein the pre-stressing members are located in an area between the tilt axle bearing and the tilt mechanism.
  • 19. The engine of claim 18, further comprising collars rigidly connected to the crankcase part and to the cylinder receiving part and the pre-stress members are applied to the collars.
  • 20. The engine of claim 19, wherein the pre-stressing members comprise either a compression spring stack or hydraulic force generators.
  • 21. The engine of claim 1, wherein the pre-stressing members comprise either a compression spring stack or hydraulic force generators.
Priority Claims (1)
Number Date Country Kind
9900986 Mar 1999 SE
PCT Information
Filing Document Filing Date Country Kind
PCT/SE00/00498 WO 00
Publishing Document Publishing Date Country Kind
WO00/55483 9/21/2000 WO A
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Number Name Date Kind
2770224 Ericson Nov 1956 A
3450111 Cronstedt Jun 1969 A
3633552 Huber Jan 1972 A
4174683 Vivian Nov 1979 A
5025757 Larsen Jun 1991 A
5329893 Drangel et al. Jul 1994 A
5443043 Nilsson et al. Aug 1995 A
5562069 Gillbrand et al. Oct 1996 A
5611301 Gillbrand et al. Mar 1997 A
Foreign Referenced Citations (1)
Number Date Country
07026981 Jan 1995 JP