DE2346969C3 - Arrangement for damping bending and torsional vibrations on shafts - Google Patents

Description

The invention relates to an arrangement for damping bending and torsional vibrations on waves of Machines, especially in the case of spindles of machine tools and in internal combustion engines with straight Shaft, with a sleeve surrounding the shaft with play, which in an axial section of the shaft / wipe the Radial bearings is provided and rotates freely with the shaft, the gap between the shaft and the sleeve is filled with a damping, viscous agent, in particular lubricating oil.

Such an arrangement is already known from US Pat. No. 3,552,804, for example. It runs in the area / wipe the bearings around a sleeve with the shaft, which sits tightly on the shaft at both axial ends. The thin gap, in which as a damping means, extends between the ends of the sleeve that are seated for example silicone oil is provided. The damping means is completely closed in the gap and is squeezed between the shaft and the sleeve when the shaft vibrates.

Due to the high-frequency vibrations of the shaft, the damping means, which does not vibrate rests against the shaft and the sleeve, from narrowing areas of the gap with high acceleration and pressurization is displaced into widening areas of the gap, creating a strong Damping effect can be achieved; the constant squeezing action of the damping means during operation However, the shaft also leads to a not inconsiderable increase in temperature due to internal friction of the damping agent. Since viscous damping agents on an organic basis such as oils or the like quickly become thinner at higher temperatures, the damping effect decreases after a short time

Operating time of the shaft significantly.

The object of the invention is to create an arrangement of the type indicated at the outset, in which on as simple as possible a permanently good damping effect is achieved.

According to the invention, this object is achieved in that the viscous agent passes through the gap under pressure is pumped.

As a result, constant circulation and recooling of the viscous medium is achieved, its The total volume is only exposed to a comparatively small fraction of the respective squeezing effect, so that there is only a slight increase in temperature to a rapidly reached upper value.

From DE-PS 5 12 454 it is known per se, a liquid damping agent, its internal friction is used for damping, circulating by a pump and so that by the vibration work dissipate absorbed heat. The damping takes place in a separate housing provided damping apparatus in which only torsional vibrations using a comparatively large oil; tight to be steamed. In this case are when pumping through the damping agent both

For example, completely different flow conditions in an oil circuit, Flow resistances and design considerations must be taken into account. In case of In addition, the invention has the fact that with high-frequency vibrations of the shaft an extremely fast one Pressurization and acceleration of the viscous agent takes place, so that this with longer Staying in the gap can show signs of disintegration, which in each case is disadvantageous Effects can be delayed that a considerably larger amount of viscous means in the Use is. Such aspects play against torsional vibrations in the case of an own damping apparatus, as is known from DE-PS 5 12 454, does not matter.

Due to the toughness of the damping agent and the resulting resistance to rotating relative movements According to the invention, the shaft also has a certain damping of torsional vibrations achieved. As a result of the unbraked entrainment of the sleeve on the rotating shaft, however, the A profiling of the shaft and sleeve can also be provided according to the invention, for example a serration, so that even with pure torsional vibrations through the tangential Relative movements of the shaft surface have a direct squeezing effect on the oil and as a result, there is a disproportionately stronger damping of torsional vibrations.

Advantageous further developments of the invention emerge from the further subclaims 3 and 4.

Overall, the invention thus makes a long-term, simple and reliable manner Operation achieved reliable strong damping or complete suppression of resonance vibrations.

The stresses or torsional deflections that occur no longer exceed those of the static ones Calculation / underlying values. This also results in smoothness.

Vibrations excessive due to resonance, the

^ 5 are avoided according to the invention, in particular even in the case of axial piston internal combustion engines Gears are dangerous with those with connecting rods connected swash ring against the cylinder block

Prevent rotation.

Vibrations can wedge-edged pressures / wipe the teeth of drive wheels with unpredictable Cause forces that lead to breakage. Even with machine tool spindles, such as a lathe occur especially with interrupted Cut vibrations that make the rotation image impermissible due to chatter marks and even more so the accuracy worsen. For this reason, machine tools are known to be as massive as possible designed. Due to the damping arrangement according to the invention However, the vibrations that occur can be reliably and manageable even during long periods of operation Maximum values are limited so that vibration problems are no longer caused by machine tools either expensive substantial oversizing must be resolved.

The invention is explained in more detail below on the basis of exemplary embodiments shown in the drawings. It shows

1 shows a longitudinal section through an axial piston motor with a damping arrangement according to the invention,

Fig. 2 is a partial representation of an enlarged .Schnittbereich according to line C - Cm Fig. 1,

F i g. 3 an andi ■ embodiment of the invention Damping arrangement in a Schni representation according to Fi g. 2,

4 schematically simplified in longitudinal section the Bearing area of a tool machine spindle with a damping arrangement according to the invention.

F i g. 5 shows a cross section according to line V-V from FIG. 4th and

F i g. 6 shows another embodiment of the damping arrangement according to the invention in a representation according to FIG. 5.

In the axial piston motor shown in Fig. 1 sits on one end of a shaft 1 by means of a Hub 2 is a swash plate 3. Of ball bearings 12 and 15, a wobble ring 13 is within the shell-like Out of the swash plate 3, in which on ball pins 21 foot bearings 21; / by connecting rods by means of a counter ring 25 are supported. Extend the connecting rods held with their connecting rod bearing shells with their other end in a cylinder block 40 provided in cylinder 39, in which counter-rotating pistons are moved back and forth by the combustion pressure.

As a result of the combustion forces exerted on the wobble ring 13 by the cylinders, the swash plate 3 is rotated via the ball bearings 12 and 15, the wobble ring 13 swinging back and forth around the wobble center O between the end positions shown in the drawing with solid and dashed lines. So that the wobble ring 13 does not fall into a rotational movement, it is held in a rotationally fixed manner by a rolling cone lug consisting of bevel gears 26 and 28, the bevel gear 26 being securely connected to a shoulder 27 of the wobble ring 13 with a light bearing. The bevel gear 28 is firmly connected to the end face 38 of the cylinder block 40 by means of a centering hub 29 and a stop ring 30 as well as studs 42.

Between the thrust ring 30 and a lustrous disk 31 in front of the hub 2 are at both ends of the shaft I each a radial bearing 32 is provided, which alternatively, tls Plain bearings 32.7 (see. Left side of Fig. 1) or as Roller bearing 326 (cf. right side of FIG. I) can be designed with radial bearing rollers 33.

For lubrication within the swash plate 3, the oil is added via a central oil supply 70 from an oil pump system 71. ^ o that the oil in the direction of the arrow between the swash ring 13 and Swashplate 3 flows radially upwards.

A sleeve 50 in the form of a tube is arranged around the shaft I by means of a fit which in the order of magnitude of normal bearing play

ίο or 1/1000 d. The sleeve 50 is ax.alen at its Ends between the thrust rings 30 are adjusted and moves completely freely on the surface of the shaft 1. wherein in the gap 51 located between the sleeve 50 and the surface of the shaft I a high molecular weight.

If possible, calli-flowing liquids are provided. how z. B oil or isobutylene. In this liquid damping agent, the Wave a strong damping of the bending vibrations that occur during the operation of the axial piston motor one. This damping effect is compared to a possible damping on the bearing shell of the radial plain bearing 32, v not only because the sleeve 50 is considerably larger, without increasing storage losses over almost the can extend the entire length of the shaft 1, but also because the damping fluid in the gap 51 is largely at rest, while in the Bearing gap of the radial sliding bearing 32a for homogeneous lubricating film production rotates. But if the Damping liquid or the lubricating oil is in rapid motion on the circumference of the shaft, so is for a local displacement of the liquid when vibrations occur considerably less work is required than with a cushion of damping fluid resting relative to the split walls.

The oil can be introduced into the gap 51 in various ways, for example through a or several transverse bores 75 in the middle of the motor from inside the shaft through pure Centrifugal force or under the pressure of the oil pump 71.

When bending, the gap 51 is mainly changed in its radial thickness, so that the Dänipfkrälte act hydraulically.

The shaft I and the sleeve 50 can, as in FIG. 3 is illustrated in more detail, limit the gap 51 with cylindrical walls. But if both wave 1 and also the sleeve 50 according to FIG. 2 is provided with a serration 52 or a similar profile, then the effectiveness of the sleeve 50 for damping torsional vibrations is significantly increased, since then, even with relative rotary movements, the damping fluid is squeezed against the flanks of the Serration 52 occurs.

In Fig. 1, the supply of the damping fluid by the already existing oil pressure pump 71 is from shown on the left, which is advantageously arranged near the oil collection container in a motor vehicle.

The described damping arrangement is obviously also effective if there is a corresponding one Damping body is located inside a shaft or

(10 if it is square or hexagonal instead of circular is. In the case of a polygonal cross-section, the toothing can be attached to the thickened walls. The use of a so-called K-profile is also possible.

(15 The described damping arrangement is next to the explained use in an axial piston machine, in which the occurring vibrations of particular d, f

are, for a lot of y.uh! another

applicable. In the F i g. 4 to b show a machine tool spindle for example, which has a shaft wheel 82 on a shaft 80 embodied as a hollow shaft, for example, and is mounted in bearings 81 sealed to the outside with seals 83. A vibration-damping sleeve 84 is arranged around the shaft 80, the assignment and distance of which from the shaft 80 can be selected in the manner explained in connection with the sleeve 50 according to FIG. 1. Between the sleeve 84 and the shaft 80 there is a correspondingly narrow gap 85 (FIG. 6), which can also be designed in the form of serrations 86 or another suitable longitudinal profile (FIG. 5) Shaft 80 circumferential sleeve 84 z. B. is set by means of pointed screws 87, then the damping sleeve can also serve with its end faces as a thrust bearing. The damping fluid, in particular lubricating oil, is pressed via an oil pump 81 through an opening 89 with simultaneous lubrication of the bearing 81 into the gap 85. The oil supply and also the oil drain can of course be arranged and designed in various ways.

For this purpose 2 sheets of drawings

Claims (4)

Patent claims: 1. Arrangement for damping bending and torsional vibrations on machine shafts, especially in the case of spindles of machine tools and in internal combustion engines with straight shafts, with a sleeve surrounding the shaft with play, which is in an axial section of the shaft between the Radial bearings is provided and rotates freely with the shaft, the gap between the shaft and the sleeve is filled with a dampening, viscous agent, in particular lubricating oil, d a through characterized that the viscous Medium is pumped under pressure through the gap (51,85). 2. Arrangement according to claim 1, characterized in that that the shaft (I; 80) and the sleeve (50; 84) with a profile (52; 86), for example one Serrations are provided, so that torsional vibrations also displace the steaming Means cause in the profiled gap (51; 85). i. Arrangement according to Claim 1 or 2, characterized in that the pressure supply of the damping means takes place from the shaft (I). 4. Arrangement according to claim 1 or 2, characterized in that the pressure supply of the damping By means of at least one radial bearing (81) with its simultaneous lubrication he follows.