EP0662565A1 - Hydraulic amplifier - Google Patents

Abstract

The receiver (11) has a jet divider with at least one control edge in order to divide the fluid jet directed towards it. The jet divider has a wedge-shaped point with two surfaces coming together in an acute angle. The two surfaces at their meeting point form the control edge. The wedge-shaped point of the jet divider is so flattened at its one end that an even surface is formed with two control edges, which divide the directed fluid jet. The jet divider can also be formed as a cylindrical pin (16) and the receiver has a longitudinal bore extending in the direction of the jet and two crossways arranged cross bores (14).

Description

The present invention relates to a hydraulic amplifier according to the jet pipe principle for a servo or proportional valve according to the preamble of claim 1.

Such a hydraulic amplifier usually includes an electric drive with permanent magnets and control coils that generate variable magnetic fields in response to an electrical control signal. The amplifier also has an armature, which is moved by the drive, and a jet pipe mechanically coupled to the armature, to which the movements of the armature are transmitted. The jet pipe is supplied with hydraulic fluid under operating pressure via a feed pipe. The jet pipe has an outlet nozzle from which a fluid jet emerges. Conventionally, an outlet nozzle is used, as shown in longitudinal and cross section in FIG. 4.

The nozzle 1 has the shape of a hollow cylinder, the walls of which have a sufficient wall thickness so that the nozzle still has sufficient rigidity even at maximum operating pressure. In the outlet area 2, the circular inner cross-section narrows evenly and steadily up to an outlet opening 3. The outlet area 2 consequently has the shape of a truncated cone.

The jet pipe is aimed at a receiver, the structure of which is shown in FIG. 5 from the representation of the longitudinal and cross-section. Such a conventional receiver 4 has two receiver openings 5, each of which is connected to the end faces of a control piston (not shown) of the servo or proportional valve via a corresponding oblique hole 6 and subsequent transverse holes 7.

In the zero position of the valve, the outlet nozzle of the jet pipe is directed uniformly onto both receiver openings, as a result the pressure generated in the oblique and transverse bores by the outflowing liquid is the same. As a result, the control pressure on both ends of the control piston is also the same, as a result of which the control piston remains in the zero position. If the outlet nozzle of the jet pipe is directed to a large extent onto one of the two receiver openings, the pressure in this control channel (consisting of oblique and transverse bores) increases and decreases in the other control channel. The resulting pressure difference causes the control piston to move.

It is considered disadvantageous in the hydraulic amplifier described above that its manufacture is relatively complex and therefore expensive. On the one hand, the production of the conical outlet area of the nozzle is complex, on the other hand, the execution of oblique bores in the receiver is difficult and requires multiple clamping during the machining of the workpiece, which further increases the production costs.

In addition, the known hydraulic amplifier is disadvantageous if the useful flow through the amplifier is to be increased. This is necessary, for example, if you want to increase the stability and dynamics of the amplifier. The useful flow is determined, among other things, by the diameter of the outlet nozzle and the operating pressure used. If one increases the diameter of the outlet nozzle, which is circular in cross section, in order to increase the useful flow, the so-called working stroke inevitably also increases. The working stroke is defined by the distance that the jet pipe travels in the area of the outlet opening until the emerging jet, starting from the zero position, is completely aimed at the receiver opening. In the case of an outlet nozzle which is circular in cross section, the working stroke is half the diameter of the outlet opening. For example, a jet pipe, the outlet opening of which has a diameter of 0.5 mm, must have a distance of 0.25 mm swing out to fully hit one of the two receiver openings.

However, the increase in the working stroke which is inevitably associated with the increase in the diameter of the outlet opening is undesirable. For a larger working stroke, a larger electrical control signal is required, which can only be generated with a larger and more complex circuit. Furthermore, the bending stress of an elastic bending tube, which generates a restoring moment for the movable armature, increases with an increasing working stroke. Finally, an increased working stroke also leads to a decrease in the dynamics of the hydraulic amplifier.

The present invention has for its object to provide a hydraulic amplifier that is simple and inexpensive to manufacture and in which a high useful flow and at the same time a small working stroke can be achieved.

This object is achieved according to the invention by a hydraulic amplifier with the features of claim 1.

This has the following advantages. By designing the outlet nozzle with a rectangular cross section, the useful flow is increased on the one hand compared to an outlet nozzle with a circular cross section, which leads to an increase in the stability and dynamics of the amplifier. On the other hand, the formation of an outlet opening with a rectangular cross section has the advantage that the flow can be determined over the slot width with the same slot width, ie head tube stroke. In addition, the receiver according to the invention has a beam splitter with at least one control edge in order to enable an exact division of the fluid jet directed thereon. In addition, the working stroke is reduced, namely to a distance which is equal to half the shorter side of the rectangular cross section of the outlet nozzle. The reduction in the working stroke results in lower stresses in the bending tube occur and the dynamics of the amplifier is improved. Ultimately, the effort for the production of such a receiver is also reduced, since the need for two receiver openings and the associated oblique bores is eliminated and the electronics required for generating the control signal are simply constructed.

In a preferred embodiment, the beam splitter comprises a wedge-shaped tip with two flat surfaces that converge at an acute angle. At the point where they meet, the two flat surfaces form a control edge. The design of the beam splitter in the form of a wedge-shaped tip is particularly easy to manufacture and brings excellent results with regard to the exact division of the fluid jet.

In an alternative embodiment to this, the wedge-shaped tip of the beam splitter is flattened at one end in such a way that a flat surface is formed with two control edges, which divides the fluid jet directed thereon. A beam splitter designed in this way has shown a particularly good flow behavior of the hydraulic fluid.

In a preferred embodiment, the beam splitter is designed as a cylindrical pin and the receiver has a longitudinal bore extending in the beam direction and two transverse bores arranged transversely thereto. The pin is arranged in the longitudinal bore at a point at which the flat surfaces of the beam splitter come to lie opposite the input openings of the transverse bores. As a result, the beam entering the receiver is introduced directly into the transverse bores, which results in good flow amplification. This also eliminates the need for oblique holes, which are expensive to manufacture.

The cylindrical pin is preferably installed in the longitudinal bore, as a result of which it seals against the hydraulic fluid is closed. In addition, the manufacture and assembly of a receiver designed in this way is particularly simple.

Fig. 1

einen Längs- und Querschnitt durch ein bevorzugtes Ausführungsbeispiel einer Auslaßdüse und des Empfängers nach der vorliegenden Erfindung,

Fig. 2A

einen Querschnitt, eine Seitenansicht und eine Draufsicht auf ein Ausführungsbeispiel eines Strahlteilers, der in dem in Fig. 1 dargestellten Empfänger verwendet wird,

Fig. 2B

einen Querschnitt, eine Seitenansicht und eine Draufsicht einer alternativen Ausführung eines Strahlteilers, der in dem in Fig. 1 dargestellten Empfänger verwendet wird,

Fig. 3

einen Längs- und Querschnitt durch einen Teil des erfindungsgemäßen Empfängers gemäß Fig. 1 mit dem in Fig. 2A dargestellten Strahlteiler,

Fig. 4

einen Längs- und Querschnitt druch eine herkömmliche Auslaßdüse mit kreisförmigem Querschnitt, und

Fig. 5

einen Längs- und Querschnitt durch einen herkömmlichen Empfänger, wie er mit der in Fig. 4 dargestellten Auslaßdüse verwendet wird.

The invention will be explained in more detail below on the basis of preferred exemplary embodiments with reference to the accompanying drawings. Show it:

Fig. 1

2 shows a longitudinal and cross section through a preferred exemplary embodiment of an outlet nozzle and of the receiver according to the present invention,

Figure 2A

2 shows a cross section, a side view and a top view of an exemplary embodiment of a beam splitter which is used in the receiver shown in FIG. 1,

Figure 2B

3 shows a cross section, a side view and a top view of an alternative embodiment of a beam splitter which is used in the receiver shown in FIG. 1,

Fig. 3

2 shows a longitudinal and cross section through part of the receiver according to the invention according to FIG. 1 with the beam splitter shown in FIG. 2A,

Fig. 4

a longitudinal and cross-section through a conventional outlet nozzle with a circular cross-section, and

Fig. 5

a longitudinal and cross section through a conventional receiver, as used with the outlet nozzle shown in Fig. 4.

In the hydraulic booster according to the present invention, an outlet nozzle 8 shown in FIG. 1 is used. The outlet nozzle has the shape of a hollow cylinder with a circular shape, like that in the conventionally designed outlet nozzle Internal cross section. At one end of the nozzle it tapers very sharply to an outlet area 9 and opens into a slot-shaped outlet opening 10 which is rectangular in cross section. The side lengths of the rectangular cross section are, for example, 1 mm lengthways and 0.3 mm crossways.

2A, 2B and 3 show parts of a receiver 11 suitable for the outlet nozzle described above. The receiver has only one receiver opening 12 and an adjoining longitudinal bore 13, which extends in the direction of the fluid jet emerging from the outlet nozzle. Starting from the longitudinal bore 13, two transverse bores 14 extend transversely thereto in opposite directions, which are connected to the end faces, not shown, of a control piston.

2A shows the design of a beam splitter 15 as a cylindrical pin with a wedge-shaped tip. The tip has two flat surfaces which converge at an acute angle and form an angle α of approximately 30 to 60 ° with one another. At the point where the two surfaces meet, they form a sharp control edge 17.

An alternative embodiment of the beam splitter 15 is shown in FIG. 2B. In it, the wedge-shaped tip is flattened at one end, so that a flat surface of width B and two control edges 17 are formed.

When mounting the amplifier, the beam splitter 15 is pressed into the longitudinal bore 13 of the receiver so that the flat surfaces of the beam splitter come to lie opposite the transverse bores 14.

In the zero position of the control piston, the fluid jet in the embodiment shown in FIG. 2A strikes the control edge 17 of the wedge-shaped tip of the beam splitter and is evenly divided by this. Each part of the fluid jet strikes one of the two flat surfaces at an angle of α / 2. As a result, both parts of the fluid jet are deflected in their direction and directed into the corresponding transverse bore 14. In the embodiment of the beam splitter with a flattened tip shown in FIG. 2B, the fluid jet strikes the flat surface of the width B without experiencing any deflection. In both embodiments, there is a uniform control pressure on both sides of the end faces of the control piston, as a result of which the control piston is held in the zero position.

When the armature and the jet pipe connected thereto is moved in response to an electrical control signal, the direction of the fluid jet emerging from the outlet nozzle 10 changes. When the beam splitter is designed with a control edge 17, the impinging fluid jet is separated into unequal parts. The different parts of the fluid jet create different pressures in the transverse bores of the receiver. Accordingly, a larger control pressure builds up in one of the cross bores, whereas the control pressure in the other cross bore decreases accordingly. This results in a pressure difference which acts on the end faces of the control piston and causes it to move out of its zero position.

When using the beam splitter with a flattened tip, the beam "wanders" over one of the two control edges 17 and strikes one of the two flat surfaces 18. This creates a greater pressure in the transverse bore of the receiver, which is opposite this surface 18, than in the other Cross bore, which in turn builds up the pressure difference to control the valve.

Claims (5)

Hydraulic amplifier with an outlet nozzle from which a fluid jet directed at a receiver emerges, characterized in that
the outlet nozzle (10) has an outlet opening which is rectangular in cross section and that the receiver (11) has a beam splitter (15) with at least one control edge (17) in order to divide a fluid jet directed thereon. Hydraulic amplifier according to claim 1, characterized in that the beam splitter (15) has a wedge-shaped tip with two flat surfaces (18) converging at an acute angle (α) and the two surfaces form the control edge (17) at the point of their meeting. Hydraulic amplifier according to Claim 1, characterized in that the wedge-shaped tip of the beam splitter (15) is flattened at one end in such a way that a flat surface (19) is formed with two control edges (17) which divides the fluid jet directed thereon. Hydraulic amplifier according to at least one of claims 1 to 3, characterized in that the beam splitter (15) is designed as a cylindrical pin (16) and the receiver (11) has a longitudinal bore (12) which extends in the beam direction, and two transverse bores (14) arranged transversely thereto and that the pin (16) is arranged in the longitudinal bore at a point at which the flat surfaces (18) of the beam splitter come to lie opposite the inlet openings of the transverse bores (14). Hydraulic amplifier according to claim 4, characterized in that the cylindrical pin (16) is installed in the longitudinal bore (13) in a sealing manner.

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