NL9001565A - BARRIER FOR HIGH TAXES. - Google Patents

Description

Short designation: High load pivot alloy.

The invention relates to a pivot alloy according to the preamble of claim 1.

Such alloys of alloys are known and can be made in many ways. A particular problem arises, however, because the axial load on the pontoon army is high, while the dimensions of the army must remain limited. This is especially the case with multi-screw extruders, in which the dimensions in the radial direction of the axial alloy of a shaft which is not directly driven are limited by the proximity of another shaft, while it is nevertheless necessary to absorb large axial forces, which forces are generated by kneading and propelling the material to be extruded with the screw mounted on the shaft.

A possible solution to this problem is the use of a hydrostatic self-adjusting army, fed by a pump. Due to the limited diameter of this army, however, the pressure in the army must be very high, which is subject to drawbacks due to the required non-standard high-pressure pump and fittings, which are difficult to obtain, expensive and maintenance sensitive.

If a mechanical alloy is chosen, the high army loads will lead to rapid wear of the army, so that the life of the army is limited and there is a risk of overheating and seizure.

It is known, in order to decrease the axial load on a pivot bearing, to place several pivot bearing on a shaft one after the other. However, to avoid an uneven load on each individual bearing, very high precision of machining and mounting of the bearing parts is required. With a small deviation, which can occur, for example, due to wear, one of the series' trunnions may experience an excessive load and become defective, or make too small a contribution to the axial load absorption, as a result of which the other trunnions of the series fail. In addition, the provision of several pivot armies is difficult from a cost perspective.

The object of the invention is to provide a pivot alloy which is reliable, does not need to be machined and mounted particularly precisely and can therefore be manufactured at a low cost.

These objects are achieved with the measures according to claim 1.

The pivotal alloy of the pivotal alloy according to the invention is in operation subjected to a relatively low load due to the use of the cylinder-piston units, which can be particularly simple in construction.

A particularly efficient construction of the pivot alloy is obtained in the embodiment according to claim 2, in which seals can be arranged between the bearing housing and the shaft. A very precise finish or assembly of the parts of the cylinder-piston units is not necessary, making the alloy inexpensive.

The manufacturing costs of the alloy can be further reduced with the measures according to claims 3 and / or 5. By applying equal parts, an equal pressure medium and an equal pressure in all cylinder-piston units, the construction of the alloy is simple, while only one pump is required for all cylinder-piston units.

After each element on the shaft (cylinder-piston unit or pivot bearing) that absorbs an axial partial load, the remaining axial load is lower and a smaller diameter of the shaft will suffice if the mechanical tension in the shaft remains the same.

The effective surface area of each piston connected to the shaft increases with decreasing shaft diameter and thus a lower pressure of the medium suffices with the same radial dimensions of the alloy.

Extremely advantageous embodiments of the alloy according to the invention are described in claims 6 and 7. The self-pressure-adjusting property of the hydrostatic bearing is used in this way to determine the pressure in the cylinder-piston units, so that with a certain dimensioning of the bearing parts the total axial load is distributed in a fixed mutual ratio between the cylinder-piston units and the hydrostatic bearing.

The pivot alloy according to the invention is particularly intended for use in a multi-screw extruder, where a large axial load must be able to be accommodated with small radial dimensions of the alloy.

The invention therefore also relates to an extruder which is provided with at least one pivotal alloy according to the invention.

The invention is elucidated with reference to the drawing, which schematically shows, in partial longitudinal section, a preferred embodiment of the pivot alloy according to the invention.

In a bearing housing 2, an axially loadable, rotatable shaft 6 is received which is axially loadable in the direction of arrow 4. The hydrostatic alloy comprises a bearing disc 8, a bearing cup 10 fixedly connected to the bearing housing 2 with a hollow core and a movable intermediate bearing disc 12 with a hollow core arranged between the bearing disc 8 and the bearing cup 10. The intermediate disc has a partially spherical side that fits and is movable in a partially cup-shaped side of the army cup 10. The other side of the intermediate disc 12 is substantially flat, as is the opposite side of the bearing disc 8.

Both said flat sides have an axial collar on the edge, between which collars can develop in a gap 14 when the shaft 6 moves against the direction of arrow 4.

By supplying a medium under pressure, for example oil, via supply opening 16 to the hydrostatic bearing, the bearing disc 8 is forced away from the bearing cup against the bearing cup by a force which depends on the pressure of the medium and the active surface of the bearing disc. 10 intermediate bearing disc 12, as a result of which the gap 14 increases and the supplied pressure medium can flow away to a discharge opening 18. The pressure in the hydrostatic army thereby decreases again. Opposite this force on the bearing disk 8 is the axial force exerted on the alloy in the direction of the arrow 4. A balance of forces is established here. This force equilibrium is achieved at a certain gap width, depending on the pressure-volume characteristic of the pump 19 used for pressurizing the pressure medium and the viscosity of the oil.

A gap width actually occurring in an extruder is very small, namely about 30 micrometers in size. The construction of the alloy is such that this width can increase to a maximum of 40 micrometers when the extruder is out of operation.

A number of discs 20 are mounted on the shaft 6, which discs are virtually sealed at the outer edge axially against the inner wall of the bearing housing 2 by means of sealing means (not shown). Each disc 20 can move axially and tangentially in a cylindrical space within the bearing housing 2. Each cylindrical space is substantially sealed against the shaft at both axial ends by means of sealing means (not shown). In the bearing housing 2, supply openings 22 for a pressure medium are provided, which openings open on one side of each disc. The space on the other side of each disc communicates with a discharge opening 24, so that any pressure medium leaked into this space can be discharged without pressure. This arrangement allows each disc 20 to transmit a force to the shaft 6.

The discharge openings 18 and 24 are in open communication by means of a pipe 25 to a pressureless reservoir 27, from which the pump 19 draws pressure medium.

The force exerted on the shaft by the hydrostatic bearing and the cylinder-piston units must be in equilibrium with the axial force acting in the direction of arrow 4 for a good alloy. In the embodiment shown in the drawing, this is achieved in a simple manner by connecting all supply openings 22 by means of a conduit 23 to the pressure medium supply opening 16 for the hydrostatic bearing, whereby the slit 14 throughout the alloy pressures the pressure medium. determines. As a result, the axial load is taken up in a constructively determined ratio by the hydrostatic bearing and the associated cylinder-piston units.

However, it is also possible to supply the cylinder-piston units with a medium with a fixed or variable pressure, separate from the pressure medium supply of the hydrostatic bearing.

By placing a certain number of cylinder-piston units on the axially loaded shaft one behind the other, it is possible to construct a pivot alloy with a limited diameter and a limited maximum pump pressure, which can take a large axial load.

A pump with a maximum pressure of 22 MPa, which is commercially available as a standard hydraulic pump, can have a three-disc pivot alloy 20 absorb the same load as a pump with a maximum pressure of 60 MPa, in the absence of the discs 20. The latter pump is non-standard and is only made to order.

The spacing of the pivot bearing and the cylinder piston units on the shaft is not essential; it is also possible to place not one of the pivot bearing, but one of the cylinder piston units at the end of the shaft.

Claims (8)

1. Pivotal alloy, in particular for a multi-screw extruder, comprising: an axially loadable rotatable shaft; an army house in which the shaft is radially alloyed; and at least one pivot bearing mounted in the bearing housing and on the shaft for receiving an axial load on the shaft, characterized by at least one cylinder-piston unit arranged and connected between the shaft and the bearing housing, comprising two parts movable relative to each other, the first part of which is connected to the bearing housing and the second part to the shaft, each cylinder-piston unit being arranged to exert an axial force on the shaft by means of a medium supplied to it under pressure, such that the cylinder-piston unit absorbs part of the axial load, with the pivotal bearing the remaining axial load not absorbed by cylinder piston units. 2. Pivotal alloy according to claim 1, characterized in that the cylinder-piston units are arranged one behind the other in axial direction, the cylinders thereof being connected to the bearing housing and the pistons being connected to the shaft. Pivot alloy according to claim 1 or 2, characterized in that all cylinder-piston units are equal. Pivot alloy according to claim 1 or 2, characterized in that the diameter of the shaft decreases stepwise in the direction of the axial load after each partial load-absorbing element. Pivot alloy according to any one of the preceding claims, characterized in that the pressure sides of the cylinder-piston units are mutually connected. Pivot alloy according to any one of the preceding claims, characterized in that the pivot alloy is a hydrostatic, self-adjusting bearing, the pressure side of which communicates with the pressure side of the cylinder-piston units. 7. Pivotal alloy according to claim 6, characterized in that the pivotal alloy is arranged on one end of the shaft and the cylinder-piston units immediately before it. Extruder provided with at least one pivot alloy according to one or more of the preceding claims.