DE3844413A1 - Multiple armature magnet - Google Patents

Abstract

An electronic actuation magnet having a housing (12) in which an armature is arranged so as to be movable to and fro and having electrically actuable exciter means, preferably in the form of an exciter coil, in order to effect movement of the armature, the armature being constructed in many parts, especially two parts, and the armature parts being displaceable relative to one another.

Description

The invention relates to an electrical actuation magnets, especially an electric proportion magnetic magnets.

Known actuation or proportional magnets have in all mean a housing in which an anchor reciprocates is stored in bar. An excitation coil surrounding the armature causes when an electrical current signal to the coil is created, a displacement of the anchor. The anchor can then directly or for example via a plunger, for example wise operate a hydraulic device. The piston is preferably also used as the hydraulic device of a directional valve in question. In the case of a proportional magnet to which the invention preferably relates depending on the size of the supplied to the excitation coil Current, for example, the piston of a valve more or shifted less. This way the connection between a pump and a consumer.

If it is in the operation of a magnet of the above type there is a loss of excitation, for example, that the electronics providing the control current fail or a wire breaks in the excitation coil or the lead, so can in the hydraulic device connected to the magnet undesirable events occur. For example, in the case of a directional control valve actuated by the magnet  Pressure rise in one or the other consumer occur. If the consumer is a hydrau acts like a cylinder, if it is in such a cylinder Case is pressurized at full speed "drive away".

In order to avoid this problem, it is already known that one with a proportional directional control valve on both sides of the Valve piston provides a proportional magnet. Then should one of the magnets is de-energized by some kind of interference, so the other magnet is automatically de-energized, so that a centering spring moves the piston into its central position can move. Such an approach naturally does two Magnets necessary, as well as twice the effort Electronics. In addition to increased costs, there are also technically less favorable conditions insofar as the valve overall will be slower because of the two magnets the mass and the friction also double. Advantageous is the good implementation of a so-called "fail safe" option, d. H. failover.

Another way to avoid pressure jumps in there is a proportional valve controlled on one side in it, when the magnet is de-energized by the in its end position of the magnetic armature to shut off the pump channel to be provided to consumers (e.g. A and B). This requires a specially trained piston, whereby but it is still briefly to a full Pressure comes to the one consumer, so that for example in the case of a hydraulic cylinder, this is a short one Would execute sentence, which of course is also undesirable.

The present invention aims at an electromagnetic To provide actuation magnets, in particular proportional magnets,

in particular for a one-way controlled proportion  tionalventil such, the disadvantages of the prior art be avoided. In particular, the invention Magnet practically a display device for its de-energized show speed. This display device should be fully in the Magnets can be integrated and in its normal operation act supportive. In connection with a directional valve should be undesirable even if the magnet excitation fails Operations, such as pressure jumps, to consumers in more efficient Way to be avoided.

According to the actuation or proportional magnet a failure indicator for the excitation current in the Form of a multi-part, in particular two-part anchor. One anchor part can be very bad in the event of a power failure quickly move to a position that this power failure signaled to operate a valve, for example, which in turn ensures safe separation of the pumps ducks by consumers.

Preferred embodiments of the invention result from the Subclaims.

Further advantages are revealed by the objectives and details of the invention itself from the description of exemplary embodiments on the basis of the Drawing; in the drawing shows:

Fig. 1 shows a longitudinal section through a first embodiment of a proportional magnet designed according to the invention, which has several (in the case shown two) anchor parts, here this proportional magnet for actuating a hydraulic device in the form of a directional valve shown in longitudinal section is Darge , so that Fig. 1 overall shows a first embodiment of a unidirectional proportional directional control valve;

Fig. 2 shows the proportional magnet of Fig. 1 in its non-energized or rest position, but here in contrast to Fig. 1, the spring bias acting on the plunger to the right is not shown and also a shut-off valve for the directional control valve provided adjacent to the right plunger end something is changed;

Fig. 3 is the proportional solenoid of Figure 2 in a excitation or operating position.

FIG. 4 shows the proportional magnet of FIG. 1 immediately after the failure of the excitation, where the one armature part of the proportional magnet has already moved to the left, so as to cause the shutoff valve to open;

FIG. 5 shows the proportional solenoid of Figure 2 in its induced by failure of the excitation rest position, which coincides with the position according to Fig. 2.

Fig. 6 schematically shows a one-way controlled proportional valve using a proportional magnet with a mechanical indicator of currentlessness (second embodiment of a one-way controlled proportional valve according to the invention);

Fig. 7 shows a third embodiment of a one-way controlled proportional valve according to the invention especially using a magnet according to Figures 1 to 5 and using a hydraulic shutdown valve.

Fig. 8 shows a fourth embodiment of an inventive controlled proportional valve on one side, wherein, in contrast to Figure 7, the shut-off valve is integrated in the way of a slide valve and the proportional magnet as well as the directional control valve are shown in a working position.

Fig. 9 shows a view similar to Figure 8, the proportional solenoid immediately after the failure of the excitation, with the shut-off valve already open;

Fig. 10 shows a representation similar to Figure 9, the Pro portionalmagneten in its caused by failure of the excitation switch-off or rest position and the directional valve in its switch-off position.

Fig. 11 shows a fifth embodiment of an inventive unidirectional proportional valve in longitudinal section;

FIG. 12 is a sixth embodiment showing of a proportional valve of the invention in the form of a specification of the embodiment according to Figure 11 and using a second embodiment of a proportional magnet according to the invention, wherein the proportional valve is shown ready for operation in its neutral position here.

FIG. 13 shows the sixth exemplary embodiment according to FIG. 12 in its switch-off position, ie the connection between the pump and the two consumers is blocked.

Fig. 14 Characteristics of the proportional magnet of FIG. 1.

1. Overview

In the following, with reference to FIGS . 1 to 5, a trained according to the inven tion proportional magnet 2 (first embodiment example of the proportional magnet) will be explained, namely ver used for actuating a hydraulic device designed in the form of a directional control valve 3 , so that overall a one-sided controlled proportional valve 1 (first embodiment of the proportional valve) is formed, which will be considered in more detail below. The proportional valve 1 according to the invention can, but does not have to be used as a pilot valve.

Before the proportional magnet 2 is described in detail with reference to FIG. 1, reference should also be made to the generalizing FIG. 6, which shows schematically the overall structure of a one-sided controlled (working against a spring 13 ) proportional valve 180 . It can be seen in Fig. 6 that the proportional magnet 2 has a mechanical display device 5 for its currentlessness and a plunger 6 . Via the tappet 6 , the tappet effect indicated by the arrow 7 is transferred to the directional control valve 3 for its adjustment. On the other hand, the mechanical display device 5 , if Stromlo liquid occurs, for example due to a cable break, a mechanical power failure signal, indicated by arrow 8 , transmitted to a shutoff valve 9 . Characterized in that the mechanical failure signal 8 actuates a switching element 50 of the valve 9 , the directional control valve 3 is connected to the tank 11 via line 10 and valve 9 , whereby the directional control valve 3 is brought into a position in which undesired connections between the pump and consumers are not are available.

2. First embodiment of a proportional magnet 2

The proportional magnet 2 has a schematically illustrated housing 12 , in which a longitudinal bore 58 is formed, in which a multi-part (in the illustrated embodiment, for example, a two-part) proportional magnet armature 4 is arranged so that it can be moved back and forth. The proportional magnet armature 4 thus consists in the illustrated case of a proportional magnet armature part 60 and a so-called holding magnet armature part 61 . The two armature parts 60 and 61 work together in proportional operation of the magnet 2 as a unit in order to effect the adjustment of the directional valve 3 which is yet to be explained. The proportional magnet armature part 60 is of a cup-shaped shape overall and is attached to the plunger 6 . The plunger 6 is guided to move back and forth in two bearings 68 and 69 , the bearing 68 being located in a tapered section of the longitudinal bore 58 , while the bearing 69 is arranged in an outwardly opening, likewise tapered section of the longitudinal bore 58 . In the area of the bearing 69 , a bush 72 is attached to the plunger 6 , in which three bores 73 are arranged with the same circumferential spacing, which are also aligned with three longitudinal bores 59 in the proportional magnet armature part 62 and accommodate pins 70 . The pins 70 protrude into a recess 65 of the armature part 62 and can transmit the force of the holding magnet armature part 61 to the hydraulic device 3 . The holding magnet armature part 61 has a bore 67 so that it can slide back and forth on the plunger 6 . The holding magnet armature part 61 is disk-shaped as a whole and projects into the recess 65 with a projection 66 which has an end face 71 for contact with the pins 70 .

As is usual with a proportional magnet, the proportional magnet armature part 60 and the holding magnet armature part 61 are surrounded by an excitation coil 64 , so that the magnetic field lines 57 can spread when excited. The feed lines for the excitation coil 64 are shown schematically at 75 .

The proportional magnet 2 , which can also be any electrical actuating magnet in general, is thus characterized by a multi-part armature, in particular a two-part armature. The proportional magnet armature part 60 and the holding magnet armature part 61 , as already mentioned, form a common displacement unit in the operating state, but otherwise these two armature parts 60 , 61 are displaceable relative to one another.

The holding magnet armature part 61 has a small mass compared to the proportional magnet armature part 60 . The magnetic part 61 preferably delivers a high force but a small stroke when excited, while the proportional magnet armature part 60 provides relatively little force but a large stroke.

An air gap is provided between the two armature parts; and further there is another air gap between the proportional magnet armature part 60 and the housing 12 (seen in the axial direction). In this way, the magnetic flux of the excitation coil 64 passes through the two air gaps in succession. It can be seen in particular in FIG. 1, where the magnetic field lines are also shown, that the magnetic flux is introduced essentially radially into the holding magnet armature part 61 , while the magnetic flux exits the horizontal magnet armature part 60 essentially axially and enters the housing 12 . For reasons of force, the first air gap (the air gap between the two magnetic armatures divide) is preferably smaller than the second air gap. Characterized in that a single common coil acts on the two armature parts 60 , 61 in one direction, both have the same direction of action.

According to the basic idea of the invention it is provided that the  minimal excitation current is sufficient for the proportional magnet should be large to a high force in the holding magnet armature part generate so that it can generate a large force which biases a spring, which in turn should be strong, so it opens quickly.

In particular, the holding magnet or the holding magnet armature should part in its closed position with the smallest occurring Control current of the proportional magnet is a very large force generate so that the strong spring can be biased. To for this purpose, the holding magnet is designed such that it has a hyperbolic characteristic.

It should be pointed out here that a second exemplary embodiment of a proportional magnet denoted by 176 is explained below with reference to FIGS. 12 and 13.

To work proportional magnets 2 , it should be noted that, as shown in FIGS . 2 to 5, in the operating state according to FIG. 3, the two armature parts 60 and 61 work together to adjust the hydraulic device 3 in the manner of a proportional magnet. However, if the current for driving the excitation coil 64 fails, for example by interrupting the feed line 75 , the holding magnet armature part 61 can, as shown in FIG. 4, quickly spring under the action of a valve opening ( 56 in Fig. 1) are moved into its rest position, which immediately gives a mechanical display for this power failure. The sluggish proportional solenoid armature part 60 then follows after, so that, finally, as shown in Fig. 5, the two anchor parts 60 and 61 reach their rest position.

3. Intermediate remark

In the following, a preferred application of the actuation magnet, which is designed in particular as a proportional magnet 2 , will be discussed. This preferred application is a one-way proportional valve. A first embodiment of such a proportional valve 1 is shown in Fig. 1. A second, more general, exemplary embodiment of such a proportional valve 180 , already briefly mentioned above, is shown in FIG. 6, a third exemplary embodiment of the proportional valve 181 is shown in FIG. 7, and a fourth exemplary embodiment 182 of the first exemplary embodiment is shown in FIGS. 9 and 10. FIG. 11 shows one fifth exemplary embodiment of a proportional valve 183 of a proportional valve 184 .

4.First embodiment of a proportional solenoid valve.

First, with reference to FIG. 1, he explains the proportional valve 1 , specifically as the basis for the description of the second ( FIG. 6) and third ( FIG. 7) exemplary embodiment.

The directional control valve 3 comprises a valve housing 14 , in which a longitudinal bore 15 is formed, in which a piston, generally designated 17 , which has a total of two piston parts 18 , 19 is arranged. The housing 14 forms, adjacent to the housing 12 of the proportional magnet 2 fastened to the housing 14 , a piston end space 20 into which the plunger 6 already mentioned protrudes. Then 14 annular spaces 21 to 25 and a piston end space 26 are provided in the housing. The piston end space 26 is closed by a plug, not shown, on which springs to be described are supported. Connection channels 28 to 32 are connected to the annular spaces 21 to 25 , these connection channels being able to be connected to tank T , consumer A , pump P , consumer P and again tank T. The piston 17 forms ring webs 33 to 37 , with recesses 38 to 40 provided between them. Radially extending recesses 41 and 42 are provided in the webs 35 and 36 , which work together with corresponding edges of the valve housing in order to effect the metering of the pressure medium (preferably hydraulic oil). The piston 17 has in its left area an extension 43 against which the plunger 6 can rest in order to move the piston 17 in accordance with the excitation of the magnet 2 .

The annular space 23 is connected via a diaphragm 44 with a connecting the annular spaces 20 and 26 connecting channel 52 .

Furthermore, the annular space 21 through a radial bore 46 is in the piston 17 with an axial bore 47 in compound is at least one radial bore 48 in the extension 43 having a recess 49 in connection. In the position shown in FIG. 1, the recess 49 is covered by a valve sleeve (switching element) 50 (already mentioned) having a radial bore 51 , so that in the closed position of the valve 9 thus formed, the end space 20 is not connected to the connecting channel 28 (tank connection T ) is connected.

The valve sleeve 50 of the shut-off valve 9 is biased by a spring 56 with the force F 2 to the position shown in Fig. 4 the open position of the valve 9. The spring 56 rests on the one hand on an end face of the piston 17 , surrounds the projection 43 and on the other hand rests on an annular flange 77 of the sleeve 50 . On the end face 74 of the sleeve 50 pointing to the proportional magnet 2 , the already mentioned three pins 70 can rest in order to transmit the force component generated by the holding magnet armature part 61 to the sleeve 50 .

It should be mentioned in this connection that the plunger 6 is biased by a spring 54 with the force F 3 against the piston 17 (weak ??). This spring 54 is shown extremely schematically in FIG. 1. The spring 54 is supported on the one hand on the housing 12 and on the other hand on an angular part 78 . The angular part 78 is attached to bushing 72 , which in turn is attached to the plunger 6 .

The piston 17 is under the influence of two springs 53 and 55 on the right. The spring 53 generates a force F 3 and the spring 55 a force F 1 each acting on the piston 17 to the left.

As already mentioned, the piston 17 has two piston parts 18 and 19 , which in the switching position shown in FIG. 1 lie on one another with their two end faces 87 , 88 in the region of the annular space 23 .

In the switching position shown in Fig. 1, the piston 17 is moved somewhat to the left out of its neutral position, so that the pressure of the pump P (not shown) is distributed somewhat unevenly between consumer A and consumer B. Assuming, for example, a pump pressure of 200 bar, the pressure in consumer A can be 120 bar and in consumer B 80 bar. If the piston 17 were in its precise neutral or middle position (middle cut), a pump pressure of 200 bar would be divided into 100 bar at consumer A and 100 bar at consumer B.

In order for the piston 17 to be in its central position or any working position shifted to the right or left relative to the central position, the proportional magnet 2 must be excited. By increasing the excitation, the piston 17 can be shifted further to the right by reducing the excitation further to the left. The force generated by the proportional magnet armature 4 is designated FP . The proportion of force generated by the holding magnet armature part 61 is designated FH . When FP reaches its maximum values, the piston 17 is in its right extreme position, with a medium force in its middle position and with a low force in its left extreme position.

The forces exerted by the springs 54 ( F 3 ), 56 ( F 2 ), 53 ( F 3 ), 55 ( F 1 ) are indicated in the brackets.

Regarding the operation of the proportional valve 1 , normal operation has already been mentioned above. The case of a power failure in the electronics of the excitation coil 64 or in the feed line 75 of the coil 64 will now be discussed. In the event of a power failure, the excitation ceases, so that both the force FH and the force FP are lost . After the holding magnet armature part 61 has only a relatively small mass, it is moved to the left immediately after the power failure by the force F 2 of the spring 56 , as shown in FIG. 4. As a result, the valve 9 is opened, with the result that the pressure in the piston chambers 20 and 26 drops to the tank pressure. As a result, the pump pressure in the annular space 23 has the possibility of pushing the two piston parts 18 and 19 apart, as shown in FIG. 10 (the modification of the exemplary embodiment according to FIG. 1). By pushing the piston parts 18 and 19 apart, the connection between the pump connection channel 30 and the consumer connection channels 29 and 31 is securely blocked, so that the consumers connected to A and B are not exposed to pressure jumps.

Of course, when the piston part 19 moves to the left, the plunger 6 and thus the proportional magnet armature 60 are also returned to their rest position, as shown in FIG. 5.

5. Second embodiment of a proportional solenoid valve

FIG. 6 shows a second, more general exemplary embodiment of a proportional valve 180 controlled on one side. Here it is indicated that a mechanical device 5 is generally provided for the de-energization of the proportional magnet 180 (practically formed in FIG. 1 by the holding magnet armature part 61 ). As in FIG. 1, the directional valve 3 , which is biased in one direction by a spring 13 , is actuated by the tappet 6 of the proportional magnet 2 . The shut-off valve 9 is connected via a line 10 with the directional control valve 3 on the one hand and via a further line with the tank on the other hand. The switching element 50 of the shutdown valve 9 is actuated by a signal 8 provided by the mechanical device 5 indicating the power failure.

It is also conceivable to provide an electrical display device instead of a mechanical display for the currentlessness of the proportional magnet 2 , which then supplies an electrical signal that indicates the failure of the proportional magnet. This electrical signal could then actuate an electrically actuated valve and open a corresponding switching element 50 in a corresponding valve 9 .

6. Third embodiment of a proportional solenoid valve

Fig. 7 shows using the basic structure of the first exemplary embodiment from a third embodiment of a one-sided controlled proportional valve 181 . Here is generalized over the first embodiment Darge provides that the shut-off valve 9 does not necessarily have to be integrated in the valve.

7. Fourth embodiment of a proportional solenoid valve

Fig. 8 to 10 show a fourth embodiment, namely a modification of the proportional valve shown in Fig. 1, which is here designated by 182.

The following differences exist with respect to the first exemplary embodiment. First of all, the spring 54 of the first exemplary embodiment is to be presented here acting between the left end of the plunger 6 and part of the housing 12 , so that the plunger 6 is biased towards the right against the armature 17 in a manner similar to that in FIG. 1.

Further, FIG 8, the piston is in accordance. 17 biased by a single spring 155 to the left, which takes over the function of the springs 1 53, 55 in Fig..

Finally, the sleeve 170 corresponding to the sleeve 50 is formed without a bore 51 and without a flange 77 . The sleeve 170 immediately releases the radial bore (s) 48 or the recess 49 . The spring 56 lies with its left end un directly on the right end face of the sleeve 170 .

Apart from these changes, the same applies to this modification of the first exemplary embodiment according to FIGS. 8 to 10 as for the first exemplary embodiment according to FIG. 1.

Fig. 8 shows the proportional valve 182 in a working position slightly shifted to the left relative to the central or neutral position. Fig. 9 shows the moment of power failure of the proportional magnet 2 , where the holding magnet armature part 61 has already moved to the left and the opening of the switching valve 9 made possible. Fig. 10 shows, finally, the pushed-apart piston members 18 and 19, which make a connection between the pump supply passage 30 and the connecting channel 29 to the consumer A and the connection channel 31 to the consumer B impossible.

8. Intermediate remark

Special modifications of the exemplary embodiment of FIG. 6 are explained on the basis of the two following exemplary embodiments, a fifth exemplary embodiment ( FIG. 11) and a sixth exemplary embodiment ( FIGS. 12 and 13). In the fifth and sixth exemplary embodiment, the pretensioning force for the valve piston is generated indirectly hydraulically, and by actuating the valve 9 , the pretensioning force can be quickly eliminated if the proportional magnet fails.

9. Fifth embodiment of a proportional solenoid valve and second embodiment of a proportional magnet

FIG. 11 shows the fifth exemplary embodiment of a proportional valve 183 which is actuated on one side, namely consisting of a proportional magnet 82 according to the invention and a directional valve 83 according to the invention.

The proportional magnet 82 is in itself a second exemplary embodiment of an electrical actuating magnet having a multi-part proportional magnet armature 76 , as was first described with reference to FIG. 1. It should therefore be briefly discussed the proportional magnet 82 , of whose proportional magnet armature 76 only a section 85 of the proportional magnet armature part 91 and a section 81 of the holding magnet armature part 90 are shown only schematically. Section 81 is practically the mechanical display device for the failure of the proportional magnet 82 . This display device 81 provides a mechanical power failure signal in the event of a power failure in the electronics of the excitation coil (not shown here) or in the event of a cable break, which is indicated by the dashed arrow 8 . By this mechanical signal 8 , the shut-off valve 9 can be switched to its open position in order to eliminate the bias of a piston 84 of the directional valve 83 to be written.

In the case of the proportional magnet 82 , the holding magnet armature part 90 is arranged such that it can be moved back and forth in a centrally arranged longitudinal bore 89 of the proportional magnet armature part 91 . In practice, the holding magnet armature part 90 has a plate-shaped part, as shown in FIG. 1, the rod-shaped section 81 only shown in FIG. 11 extending into a recess 156 in the armature part 91 .

As far as the fifth embodiment of the proportional solenoid valve 183 is concerned, reference is made to the description below of the directional valve 103 .

10. Sixth embodiment of a proportional magnet valve

In the sixth exemplary embodiment according to FIGS. 12 and 13, a proportional valve 184 controlled on one side has a proportional magnet 176 and a directional valve 103 . In contrast to the fifth embodiment shown in FIG. 11, the on-off valve 9 is integrated in the proportional valve 184 .

Of the proportional magnet 176 , only the section 85 of the proportional magnet armature part 91 and the rod-shaped section 81 of the holding magnet armature part 90 can be seen (as in FIG. 11). Unlike in FIG. 11, a valve cone 159 is formed on section 81 , which is surrounded by a flange on which an opening spring 160 is supported, which on the other hand abuts the flange part 152 of a stopper 150 .

The directional control valve 103 has a valve housing 101 with a longitudinal bore 102 , in which a piston 104 is arranged so that it can be moved back and forth. The piston 104 is penetrated by a centrally arranged longitudinal bore 179 , which comprises a larger diameter bore section 105 and a smaller diameter bore section 106 . In the bore section 106 , a biasing piston 107 is arranged so that it can be moved back and forth. A longitudinal bore 108 passes through the biasing piston 107 , which has a stop flange 109 for abutment against a ring stop 110 . The ring stop 110 is formed by the different diameters of the sections 105 and 106 . At the end opposite the flange 109 , the biasing piston 107 carries a spring plate 111 , on which a biasing spring 112 is supported, which also abuts a stop surface 122 of a stopper, not shown.

Piston end spaces 117 and 118 are formed in the housing 101 on the two end faces of the piston 104 . The piston end space 117 forms opposing stop surfaces 119 and 120 . The piston end space 118 has opposite stop surfaces 121 and 122 , the latter of which has already been mentioned.

A first centering spring 127 bears against the abutment surface 119 , which on the other abuts against a disk 123 which in turn can abut against the abutment surface 120 . Furthermore, a second centering spring 128 sits between the stop surface 122 and a disk 124 , which in turn can rest against the stop surface 121 .

A connecting channel 130 establishes the connection between the piston end spaces 117 , 118 . The connecting duct 130 is also connected via a connecting line 147 to tank 11 or a tank connecting duct 139 .

The piston 104 has recesses 132 , 133 and 134 , which can establish the connection with connection channels 139 to 143 . Adjacent to the longitudinal bore 102 , annular spaces 136 and 137 are provided in the housing 101 in the region of the connection channels 140 and 142 . An aperture 44 connects the interior portion 114 formed by the bore 105 with the recess 133 .

The interior 114 is completed at its left end by the plug 150 fastened in the piston 104 . A stepped longitudinal bore 151 is formed in the plug 150 , which forms a seat 153 which interacts with the cone 159 and thus the shut-off valve 9 . At the other end of the interior 114 is the preloading piston 107 , in whose longitudinal bore 108 a pressure compensation piston 162 is arranged, which is connected via a rod 161 to the cone 159 .

In Fig. 12, the proportional valve 184 was in a Betriebszu, namely shown in its zero position. The Proportio nalmagnet 176 is energized, that is, the shut-off valve 9 is closed, so that the pump pressure has built up in the interior 114 via the orifice 44, which has caused an extension of the preloading piston 107 and thus a tensioning of the preload spring 112 . If there is pressure in the interior 114 , the biasing piston 107 comes to a stop and the biasing spring 112 , which is strong relative to the centering springs 127 , 128 , is preloaded in a defined manner. Since the centering springs 127 , 128 are relatively weak, they can be overpressed in one direction by the proportional magnet 176 and in the other direction by the stronger biasing spring 112 .

The weak spring 160 keeps the valve 9 open when the proportional magnet 176 is not energized.

In the state shown in FIG. 12, the force generated by the spring 112 is in equilibrium with the force generated by the proportional magnet 176 (half the nominal magnetic force).

If, starting from the position shown in FIG. 12, the proportional magnetic force is made smaller, since the preload piston 107 and piston 104 have become practically one piece due to the hydraulic preload, the piston 104 is shifted to the left in order to connect P to B. The relatively weak force of the centering spring 127 is overcome. If, on the other hand, the magnetic force rises above half the nominal force, the magnet 176 will move the piston 104 to the right against the force of the biasing spring 112 and also against the force of the right centering spring 128 .

If a power failure or a cable break occurs in the area of the proportional magnet 176 , the small spring 160 opens the seat 153 very quickly because of the small mass of the holding magnet armature part 90 . The pressure in the interior 114 of the piston 104 thus collapses and the relaxing spring 112 pushes the biasing piston 107 into the piston 104 . As a result, the two outer centering springs 127 , 128 are able to center the main piston 104 via the two disks 123 , 124 , that is to say to separate pump P from consumers A and B.

Fig. 14, the explanation of the proportional magnet 1 is used as shown in FIG..

Claims (13)

1. An electrical actuating magnet with a housing ( 12 ) in which an armature is arranged to be able to move back and forth and with electrically actuable excitation means, preferably in the form of an excitation coil, in order to cause the armature to move, characterized in that
that the anchor is in several parts, in particular two parts, is built up, and
that the anchor parts are displaceable relative to one another and form a common displacement unit in the operating state, and can be moved apart in the de-energized state by means of preferably spring means. 2. actuating magnet, in particular according to the preamble of Claim 1, wherein the anchor is constructed in two parts, characterized in that the magnetic flux both Flows through anchor parts in a row. 3. Actuating magnet according to claim 1 or 2, characterized in that for a two-part magnet armature one armature part forms a holding magnet armature part ( 61 ) of a holding magnet, while the other armature part forms the proportional magnet armature part ( 60 ) of a proportional magnet. 4. actuating magnet according to one or more of the preceding claims, characterized in that the one armature part ( 61 ) has a substantially lower mass than the other armature part ( 60 ). 5. Actuation magnet according to one or more of the above outgoing claims, characterized in that the one Anchor part slidably arranged on the other anchor part is. 6. actuating magnet according to one or more of the preceding claims, characterized in that the one armature part ( 60 ) is attached to a plunger ( 6 ) on which the other armature part ( 60 ) can slide. 7. actuating magnet according to one or more of the preceding claims, characterized in that the holding magnet armature part ( 61 ) via mechanical means, preferably in the form of pins ( 70 ) outside the Mag netgehäuses ( 12 ) provides an indication of what position the holding magnet armature part is located. 8. actuating magnet according to one or more of the preceding claims, characterized in that the proportional magnet armature part ( 60 ) is formed in the overall pot-shaped with a recess ( 65 ) into which a projection ( 66 ) of the holding magnet armature part ( 68 ) he stretches. 9. actuating magnet according to one or more of the preceding claims, characterized in that the proportional magnet armature part ( 62 ) bearing plunger ( 6 ) extends to both sides of the proportional magnet armature part ( 60 ) and the holding magnet armature part ( 61 ) and at both ends in the housing ( 12 ) is stored. 10. Actuating magnet according to one or more of the preceding claims, characterized in that on the plunger ( 6 ) a bush ( 72 ) is fastened, which has bores ( 73 ) through which pins ( 70 ) extend, which on the one hand on the holding magnet armature part ( 61 ) and on the other hand can rest on a switching element ( 50 ). 11. Actuating magnet according to one or more of the preceding claims, characterized in that the holding magnet armature part ( 90 ) has a rod-shaped section ( 81 ) which extends centrally through a tubular section ( 85 ) of the proportional magnet armature part ( 91 ), with the free end of the section ( 81 ) a valve cone ( 159 ) is formed. 12. Use of the magnet according to one or more of the above claims arising from a directional valve for formation of a one-way controlled proportional valve. 13. Actuating magnet according to one of the preceding claims, characterized in that the actuating magnet is designed as a proportional magnet, the common displacement unit acting as a proportional magnet armature ( 4 ).