DE2824331A1 - FLYWHEEL FOR THE DAMPING OF TORSIONAL VIBRATIONS FOR ROTARY SHAFTS, IN PARTICULAR FOR THE CRANKSHAFT OF PISTON ENGINES - Google Patents

Description

Patent attorneys Dipl.-Ing. ΗΛΥειοκν »ανν, Dipl.-Phys. Dr. K. Fincke

Dipl.-Ing. F. A. "Weιckmann, Dipl.-Chem. B. Huber Dr. Ing.H. LisKA q 2824331

8000 MUNICH 86, DEN - ^ ₁ JUfll 1Q78

PO Box 860820

MÖHLSTRASSE 22, CALL NUMBER 98 39 21/22

1. FIAT VEICOLI INDUSTRIALI SpA
Via Puglia 35

Turin, Italy

2. S.A.G.A. SOCIETA 'APPLICAZIONE GOMMA ANTIVIBRANTI S.p.A. Via Ripamonti 88

Milan, Italy

Flywheel for damping torsional vibrations for rotating shafts, in particular for crankshafts of piston engines

809881/0756

-Jr-

Flywheel for damping torsional vibrations for Drehwel len, especially for crankshafts of piston engines.

The invention relates to a flywheel for damping torsional vibrations for rotating shafts, especially for crankshafts of piston engines.

The starting point of the invention is a vibration-damping flywheel with one of an annular plate with in radial The floating inertial mass formed in the direction of the elongated axial cross-sectional area, with an inner surface and a spacer layer of an elastomeric material covering part of a side surface of said inertial mass with L-shaped axial cross-sectional area, as well as with a drive transmission plate, which is also L-shaped in the plane of said axial cross-sectional area, the one with the intermediate layer of elastomeric material on the side face opposite the floating inertial mass is firmly connected and which is rotatably connectable to a rotating shaft.

Such a flywheel is hereinafter referred to as "the flywheel named type ".

Flywheels of the type mentioned are known from GB-PS 828 354, for example. Problems arise with such flywheels in that they must have a high performance in the damping of torsional vibrations, wherein

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the elastic energy of the oscillation is destroyed or converted into thermal energy must be converted and a correspondingly large capacity to distribute this thermal energy must be available got to. In addition, the construction and assembly should be comparatively simple. With damping flywheels of the above Art, the inertial mass is formed by a ring that has a rectangular cross-sectional area in an axial sectional plane owns.

An inertial mass connected to a drive shaft via an elastomeric intermediate member in the form of an intermediate layer generally vibrates in different vibration modes. Two of these vibrational modes are related to theirs The effect on the drive shaft is particularly significant: It is a torsional vibration, which is a torsional vibration includes the axis of rotation and an oscillation of the shaft, as well as a transverse oscillation, which is an alternating movement in a direction perpendicular to said axis.

The inertial mass of the flywheel of the type mentioned has a particularly simple rectangular cross-sectional shape. she has however, the disadvantage that the frequencies of the two above-mentioned vibration modes are usually very close to one another. This results in a comparatively complex resulting oscillation of the mass, which has a non-uniform distribution the stress in the elastomeric intermediate layer with it, which is asymmetrical with respect to the axis of rotation is. This in turn causes significant and uneven heat generation, which causes rapid deterioration of the elastic properties of the elastomeric material result.

The invention is based on the object of a vibration-damping To create a flywheel which is simple in construction, easy to assemble in manufacture, and which avoids the disadvantages mentioned above.

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This task is used for a flywheel of the type mentioned Damping of torsional vibrations, which is particularly suitable for fastening a crankshaft of a piston engine, solved in that the floating inertial mass of a widened annular part, the outer surface of which is limited by the outer radius of the flywheel itself and one with the intermediate layer made of elastomeric material connected comparatively thin-walled annular flange part is formed, the axial cross-sectional area of which has a first having radially inwardly facing area and a second area extending in the axial direction.

The inertial mass of the flywheel designed according to the invention thus consists of two parts, of which the outer one is widened Part of the actual function of the inertial mass takes over, while the inner one by a comparatively thin-walled one Flange formed part only to attach the outer inertial mass to the elastomeric intermediate layer serves. Due to the concentration of the inertial mass in a radially outer zone, the flywheel has a given Total mass related to the axis of rotation a larger polar mass moment of inertia. This increase in the mass moment of inertia is accompanied by a corresponding reduction in the frequency of the above-mentioned torsional vibration mode, while the frequency of the transverse vibration mode, which depends solely on the actual size of the inertial mass depends, remains essentially unchanged. In this way it is possible to sufficiently separate the frequencies of these modes of vibration, i.e. the two To decouple vibration modes from each other and thus undesired resulting vibrations and those caused by them to avoid uneven load distribution. From the fact that the polar moment of inertia of a flywheel changes with the fourth power of its radial dimensions, it follows that the flywheel according to the invention for a given polar moment of inertia has a mass of inertia that is considerably smaller than that of known flywheels

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Art.

In addition, the design of the inertial mass in the flywheel according to the invention allows compared to known ones Flywheels with an inertial mass of the usual shape allow more efficient heat exchange with the surrounding air. This is both to the comparatively large side area in contact with the air and to the reduced area Material thickness in the flange part of the flywheel, which is glued to the intermediate layer made of elastomeric material, so that the resulting heat has to travel a shorter path before it comes into contact with the air.

The invention is explained in more detail below with reference to the drawing:

Fig. 1 shows a side view of a vibration damping Flywheel according to an embodiment of the invention.

Fig. 2 shows on an enlarged scale an axial cross section along the line II-II of Fig. 1,

3 and 4 are fragmentary cross-sectional views showing variations of the flywheel shown in FIG.

1 with a vibration-damping flywheel is referred to, the can be attached to a crankshaft of a piston engine. The flywheel 1 has a drive transmission plate 2 with an L-shaped axial cross-sectional area and an inner annular flange 2a. There are bores 3 in the flange 2a attached to receive fastening bolts, which are used to fasten the plate 2 to the crankshaft.

An intermediate layer 4 made of elastomeric material, which also has an L-shaped axial cross-section, is means a vulcanization process on one surface of the plate 2. On the surface opposite the plate 2

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before the intermediate layer 4 made of elastomeric material is a "floating" inertial mass 5 also attached by a vulcanization process.

The mass 5 is arranged on the outside by an annular part 5 a with a rectangular axial cross section and a formed radially inwardly protruding flange 5b. The widened part 5a of the mass 5 has an inner surface 9 as well two lateral end faces 10 and 11. The flange 5b has a surface that the end face 10 of the widened Part 5a continues and which is glued to the layer 4 made of elastomeric material. The main part 14 of the flange 5b extends radially inward and ends with its inner end region at one extending in the axial direction Lip 12.

In the variants shown in FIGS. 3 and 4, those components are those of the exemplary embodiment shown in FIG correspond, provided with the same reference numerals as these.

In the variant shown in FIG. 3, the shape of the inertial mass 5 is essentially the same as in the exemplary embodiment according to FIG. 2. It differs from the latter only in that the widened annular part 5a is moved radially even further outwards. In the variant shown in FIG. 4, the widened annular part is 5a arranged on the side of the main surface 14 of the flange 5b opposite the lip 12. Thus the flange forms 5b in the variant according to FIG. 4 is a radial continuation of the lateral end face 11 of the widened part 5a. This is separated from the intermediate layer made of elastomeric material. The surface 11 points in the same direction as the axially overhanging lip 12 of flange 5b.

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Claims (4)

Claims (V) Flywheel for damping torsional vibrations for rotating shafts, especially for crankshafts of piston engines, with one of an annular plate with in radial The floating inertial mass formed in the direction of the elongated axial cross-sectional area, with an inner surface and a part of a side surface of this inertial mass-covering intermediate layer made of an elastomeric material with an L-shaped axial cross-sectional area as well as with a drive transmission plate lying in the plane of the aforesaid axial cross-sectional area is also L-shaped, with the intermediate layer made of elastomeric material on the side surface opposite the floating inertial mass is firmly connected and with a The rotating shaft can be connected in a rotationally fixed manner, characterized in that that the floating inertial mass (5) of a widened annular part (5a), the outer surface of which is limited by the outer radius of the flywheel itself and one with the intermediate layer (4) made of elastomer Material firmly connected comparatively thin-walled annular flange part (5b) is formed, the axial cross-sectional area a first radially inwardly facing region (14) and a second in the axial Has direction extending region (12). 2. Flywheel according to claim 1, characterized in that the annular flange part (5b) from the radially inwardly facing surface (9) of the widened annular part (5a) starts and has a side surface, which is a continuation of one of the two lateral end faces (11, 12) of the widened annular part (5a) forms. 3. Flywheel according to claim 2, characterized in that the annular flange part (5b) extends from the inner surface (9) of the widened annular part (5a) ra- 809881/0756 dial extends inward and has a side surface which is a continuation of the end face (10) of the widened annular part (5a) which faces the drive transmission plate (2). 4. Flywheel according to claim 2, d a d u r ch characterized, that the annular flange part (5b) extends radially from the inner surface of the enlarged annular part (5a) extends inward and has a side surface which is a continuation of that end face (11) of the widened annular part (5a) which faces away from the drive transmission plate (2). 809881/0756