DE19853635A1 - Spur gear camshaft drive for an internal combustion engine - Google Patents

Abstract

At least one intermediate balance gearwheel(18) is located between the crankshaft timing gearwheel(12) and camshaft timing gearwheel(20), and the centre pin(36) of the balance gearwheel is freely movable in relation to the crankcase(10). The free movement of the centre pin of the balance wheel is brought about by two swinging arms, one(38) of which by one side rotatably holds the centre pin of the balance gearwheel while the other side is supported on the centre pin(42) of one(16) of the gearwheels. The other swinging arm by one side rotatably holds the centre pin of the balance gear while the side lying opposite the first arm is supported in the cylinder head housing via the centre pin(44) of the camshaft gear.

Description

The invention relates to a spur gear camshaft drive for an internal combustion engine a crankcase, a crankshaft gear and a camshaft gear, according to the Preamble of claim 1.

In internal combustion engines with a camshaft drive, which is driven by several gears realized between a crankshaft and a camshaft result from several Influences of vibration loads on the camshaft drive. This is particularly the case with a diesel internal combustion engine with a work cycle in a cylinder a relatively powerful, however short term excitation of the crankshaft while at times between each Work cycles almost no torque acts on the crankshaft. This results in a relative irregular, irregular movement of the crankshaft with more or less jerky swinging movement. Tolerances in components of the camshaft drive lead to corresponding play between meshing tooth flanks of the gears, whereby vibrations in the camshaft drive can continue accordingly. On such game is additionally reinforced by the fact that steel gears or for the camshaft drive components made of steel are used, whereas Crankcase is made of aluminum. By correspondingly different Thermal expansion coefficient is thus a center distance between each Gears of the camshaft drive not during operation of the internal combustion engine more constant, which leads to additional play.

This increased play in the camshaft drive has three undesirable side effects. First, there is a synchronization between the crankshaft and the camshaft, so to speak blurred, since relative movements between the camshaft and crankshaft are possible. Especially in internal combustion engines with an integrated pump-nozzle system, in which the camshaft also directly determines the injection times, it happens Shifts in the injection times and thus to a non-optimal operation of the Internal combustion engine. Second, the uneven motion of the crankshaft is planting as vibration by the camshaft drive into the camshaft and leads there in addition to not exactly predetermined injection and valve actuation times. Third  the game leads to increased noise, which is what happens in passenger cars can be perceived as disturbing by the occupants.

A particularly large game between a camshaft gear and a last one, with the camshaft gear meshing gear of the camshaft drive also results with increasing number of gears between the crankshaft and camshaft, because Sum up tolerances and center distance inaccuracies accordingly.

The above-mentioned vibrations are further amplified by counter to a direction of rotation Forces acting on this camshaft, for example when actuating a Fuel pump of a pump-nozzle element, wherein a cam of the camshaft one has to overcome great resistance. This leads to a corresponding game in Camshaft drive to a reaction on this and corresponding Relative movements between the camshaft and crankshaft with correspondingly shifted Control times for the pump nozzle elements and valves.

Due to all of the above Disadvantages come from a camshaft drive using gears or Spur gears are practically not used in passenger cars. A camshaft drive spur gears, for example, only come at a small distance between the crankshaft and Camshaft, i.e. with the camshaft below, for use. It is Reduction of the game already provided to provide helical gears, so that the run is as quiet as possible. Nevertheless, such spur gear or gear camshaft drives so far not the comfort, smoothness and accuracy a camshaft drive with toothed belt wheels or chain wheels with roller chain.

Issued from self-study program No. 197 "The 2.8 l diesel engine in the LT '97" from Volkswagen AG, Wolfsburg, booth 08/97 is a generic spur gear Knockenweilenantrieb known, being between an intermediate gear of the camshaft and an intermediate wheel of the drive for the camshaft, a spacer fork such it is provided that a prescribed backlash is achieved. The The intermediate gear of the camshaft is arranged on a setting bearing lever, which is pivotable for mounting about an axis of rotation of the camshaft gear. To the the other intermediate wheel, the spacer fork is pivoted for assembly. After Assembly, the spacer fork is tightened so that the axis of rotation of the Intermediate gear of the camshaft is fixed.

The present invention has for its object to provide an improved spur gear To provide camshaft drive of the type mentioned above, the the disadvantages mentioned above are overcome and its possible uses without undesirable side effects in a wide variety of motor vehicles, especially in Passenger cars to be expanded.

This object is achieved by a gear camshaft drive of the above. Art solved with the features characterized in claim 1. Advantageous embodiments of the Invention are specified in the dependent claims.

For this purpose, it is provided according to the invention that between the crankshaft gear and Camshaft gear is arranged at least one differential idler gear, the axis of rotation is freely movable with respect to the crankcase.

This has the advantage that the movable differential idler gear changes Distance between axes of rotation between two adjacent gears by a corresponding relative movement of the axis of rotation of the balancing intermediate wheel is compensated, so that even when the distance between the axes of rotation of the adjacent gears changes Game occurs. As a result, timing times by the camshaft are observed more precisely and the spur gear camshaft drive runs quietly.

In a preferred embodiment, the axis of rotation of the differential idler gear is from at least two brackets are pivotally mounted, which are on the axis of rotation of the Intermediate wheel opposite ends each on fixed axes of rotation from Compensating intermediate gear pivotally support adjacent gears.

A game compensation directly on the camshaft can be achieved in that the Balance idler gear between the camshaft gear and a last idler gear of the Spur gear camshaft drive is arranged. Since the entire game of the When the spur wheel camshaft drive is added up, this results in maximum backlash compensation.

A gear ratio is expediently achieved from the crankshaft to 2: 1 camshaft in that a ratio of the number of teeth between the compensating Intermediate gear and an adjacent idler gear is selected accordingly. Here is that adjacent idler gear, for example an idler gear on the crankshaft side.  

Further features, advantages and advantageous configurations of the invention result from the dependent claims, as well as from the following description of the invention based on the attached drawings. These show in

Fig. 1 a preferred embodiment of an inventive helical camshaft drive in top view,

Fig. 2 is a sectional view taken along line II of Fig. 1 and

FIGS. 3 and 4 are exploded views.

The preferred embodiment shown in FIGS. 1 to 4 of a spur gear camshaft drive according to the invention on a crankcase 10 of an internal combustion engine, which is otherwise not shown in detail, comprises a crankshaft gear 12 , a first intermediate gear 14 , a second intermediate gear 16 , a differential intermediate gear 18 and a camshaft gear 20 .

The second intermediate gear 16 meshes with a drive gear 22 for a water pump, not shown. The crankshaft gear 12 also meshes with a drive gear 24 for an oil pump, not shown, and with a third intermediate gear 26 . The third intermediate gear 26 in turn meshes with a fourth intermediate gear 28 , which in turn meshes a drive gear 30 of a generator, not shown, and a drive gear 32 of a hydraulic pump, not shown. The second intermediate gear 16 is non-rotatably connected to a further ring gear 34 , the second intermediate gear 16 itself meshing with the first intermediate gear 14 and the further gear ring 34 with the differential intermediate gear 18 . A number of teeth of the further ring gear 34 and a number of teeth of the differential intermediate gear 18 is chosen such that there is a ratio of 2: 1 from the crankshaft gear 12 to the camshaft gear 20 .

An axis of rotation 36 of the differential idler gear 18 is freely movable with respect to the crankcase 10 and a cylinder head and is only predetermined with respect to the axes of rotation 42 , 44 of the second idler gear 16 and camshaft gear 20 by two pairs of brackets 38 and 40 . The bracket 38 rotatably holds the axis of rotation 36 of the differential idler gear 18 on one side, while an opposite side of the bracket 38 is supported on the axis of rotation 42 of the second idler gear 16 . The brackets 40 also hold the axis of rotation 36 of the differential idler gear 18 rotatably on one side, while an opposite side of the brackets 38 is supported in the cylinder head housing via the axis of rotation 44 of the camshaft gear 20 .

In this way, a respective distance between the axis of rotation 36 and the axes of rotation 42 and 44 is defined. On the other hand, the brackets 38 and 40 may include a varying angle with each other when the distance between the axes of rotation 42 and 44 changes , so that the compensating intermediate gear 18 always meshes closely with the ring gear 34 and the camshaft gear 20 with essentially no play. The brackets 38 and 40 thus form a hinge with the hinge axis on the axis of rotation 36 of the differential idler gear 18 , which spreads more or less widely due to thermal expansion in accordance with changing distances between the axes of rotation 42 and 44 . A wobbling of the compensating intermediate wheel 18 is prevented by means of disc springs 46 .

FIG. 4 shows an area of the spur gear camshaft drive hidden in FIG. 1 in the area of the camshaft gear 20 . The pair of brackets 40 is supported in the cylinder head housing via the axis of rotation 44 of the camshaft gear 20 , whereas respective ends 49 of the brackets 40 opposite the camshaft gear 20 hold the axis of rotation 36 of the compensating intermediate gear 18 ( not shown in FIG. 4). By means of a screw 48 and a sleeve 50 , the camshaft arrangement is screwed, which also includes, among other things, an encoder wheel 52 and a hub 54 .

Claims (4)

1. spur gear camshaft drive for an internal combustion engine with a crankcase ( 10 ), a crankshaft gear ( 12 ) and a camshaft gear ( 20 ), characterized in that between the crankshaft gear ( 10 ) and camshaft gear ( 20 ) at least one differential intermediate gear ( 18 ) is arranged whose axis of rotation ( 36 ) is freely movable with respect to the crankcase ( 10 ). 2. spur gear camshaft drive according to claim 1, characterized in that the axis of rotation ( 36 ) of the differential idler gear ( 18 ) is pivotally supported by at least two brackets ( 38 , 40 ) which are on the axis of rotation ( 36 ) of the differential idler gear ( 18 ) opposite ends are each pivotably supported on fixed axes of rotation ( 42 , 44 ) of toothed wheels ( 20 , 34 ) adjacent to the differential idler gear ( 18 ). 3. spur gear camshaft drive according to claim 1 or 2, characterized in that the compensating intermediate gear ( 18 ) between the camshaft gear ( 20 ) and a last intermediate gear ( 16 ) of the spur gear camshaft drive is arranged. 4. spur gear camshaft drive according to one of the preceding claims, characterized in that a ratio of the number of teeth between the differential idler gear ( 18 ) and an adjacent idler gear ( 34 ) is selected such that there is a transmission ratio of crankshaft to camshaft of 2: 1 results.