DE1550378C - Solenoid valve with a permanent magnet - Google Patents

Description

The invention relates to a solenoid valve with an armature movable in a housing, the can occupy two switching positions, an electromagnet that is switched on to the Armature exerts a force in the direction of the first switching position, and a spring acting on the armature exerts a force in the direction of the second switching position.

Such a valve is by the German Auslegeschrift 1 122 336 became known. With this must, ίο when the armature is held in the first switching position should be, by the coil of the electromagnet Electricity flow.

The invention is based on the object of designing a solenoid valve of the type defined at the outset in such a way that that the armature is kept powerless in the first switching position.

This object is achieved according to the invention in that in the magnetic field of the electromagnet a permanent magnet with variable remanence is located and that the permanent magnet by at least two electrical impulses applied to the electromagnet in one direction first magnetic state can be brought in by pulling the armature into the first switching position, and by at least two electrical pulses applied to the electromagnet in the other Direction can be brought into a second magnetic state in which the armature by the Spring can be moved into the second switching position.

This measure ensures that each time the armature is in the first switching position is located, no power is consumed. All that is needed is electricity to run the permanent magnet to change its remanence, d. i.e. to move the armature from a switching position to the. bring others. Because according to the invention the remanence with at least two pulses and is not changed with just a single pulse, electricity is also saved.

It should be mentioned that it is already known to use permanent magnets with invariable remanence for holding armatures of electromagnetic valves (see German Patent 665 565 and German Auslegeschrift 1169 242). Compared to the subject matter of the invention, these valves have the disadvantage that, in the event of mechanical vibrations, the armature can be moved out of its one switching position ^s and then, under certain circumstances, is pulled into the other switching position by the permanent magnet.

It is also already known to apply a counter-voltage pulse to the solenoid of a solenoid valve apply (German Auslegeschrift. 047 560).

Further features of the invention emerge from the subclaims.

The invention is explained in more detail with reference to the drawing. , ;;

Fig. 1 illustrates an axial section through a solenoid valve;

F i g. 2 shows a diagram from which the magnetic conditions result.

The valve shown in Fig. 1 has a housing 25, which has an inflow opening 26 for a pressurized liquid, an outflow opening 27 and an opening 28. The latter is there / .u intended, the openings 26 or 27 with a Liquid consumers, e.g. B. a hydraulic piston to connect.

The housing 25 has a cavity in which a rod 29 moves, the two valve disks 30 and 31, which alternately come to rest on the valve seats 32 and 33, respectively. The lower end of the rod 29 is guided in the bore 34 of a screw plug 35, during the upper part of the rod with the membrane 36 is firmly connected.

The underside of the membrane 36 is in contact with that supplied under pressure from the opening 26 Liquid, while the top of this membrane closes off the pressure chamber 37. The ones under pressure Stagnant liquid can pass through the channel 38 provided in the housing 25 and through the channel 38 in the part 40 located channels 39 and 41 of the pressure chamber 37 are supplied when the armature 13 is the Nozzle 18 assigned to channel 39 is not covered.

The part 40 serves to fasten the membrane 36 and is secured against the latter by a screw plug 42 clamped. This locking screw 42 carries a sleeve 14 in which the magnet armature 13 slides and the upper end of which surrounds the fixed core 11 and the permanent magnet 12. The one on an insulating body 43 seated winding 20 surrounds the sleeve 14. The magnetic field is via two ferromagnetic Discs 44 and 45 which bear against the flanges of the winding and a protective jacket 46 closed from iron.

In the position of the armature shown in Fig. 1 13, the influx of pressurized ones reaching the top of the membrane 36 becomes Liquid interrupted by closing the nozzle 18. Thus, the pressure chamber 37 is above the Channel 41 and the clearance between the armature 13 and the sleeve 14 and via the channel 47 with the Environment in connection. Thus the underside of the membrane is exposed to the pressure of the liquid, and consequently the rod 29 is moved upward so that the valve disk 30 opens and the valve disk opens 31 closes. \

If, in the opposite case, the armature 13 is in the upper position, it blocks the channel 47 and allows the pressurized liquid flowing from the opening 26 to flow into the chamber 37. The membrane pushes the rod 29 downwards and presses the valve disk 30 onto its seat. The valve disk 31 is moved into its open position. . ■ ..; ... ■ ·,. . ^:

To ensure a high level of operational safety and a stand-: fixed position of the in F i g. 1 position shown as well can also be achieved in the position of the armature 13 attracted against the permanent magnet 12, the latter is chosen so that it has a magnetization curve in which the remanent magnetism can be changed by the magnetic flux generated by the winding 20. the Fig. 2 illustrates the magnetization curve of the permanent magnet 12 and the various magnetization states of this magnet.

In this curve, the ampere turns AT of the winding 20 are plotted on the abscissa axis and the induced field B on the ordinate axis.

The magnetization curve is shown in full lines and runs over points B1, B1, B3, BA, BS, B6. If it is assumed that the field in the permanent magnet 12 has the value B 2

reached under the influence of the field generated by the winding 20 at the moment of the current interruption in this winding, the field on the part B2, B 3 would decrease if the magnetic resistance of the distance over which the lines of force of the permanent magnet 12 are closed, would be practically zero. In the case shown in FIG. 1, this ideal state is not achieved because of the air gap, so that the magnetic field of the permanent magnet 12 is symbolized by the point 54. The straight line connecting the point B4 to the zero coordinate point represents the geometric location of the possible magnetization states in the absence of an external field and with a narrow air gap in the attracted state of the armature 13. FIG. 2 shows a second straight line B 5-0 , which represents the geometric location of the possible magnetization states in the event that the armature 13 is removed from the permanent magnet 12 under otherwise similar conditions as described above.

It should be noted that the point B 4 is located above the dashed line BKR , which represents the critical field in which the magnetic attraction force in the attracted position of the magnet armature 13 is equal to the retraction force of the spring 19. If the magnetic attraction force and the force of the spring 19 in the position of the magnet armature 13 remote from the permanent magnet are equivalent, the corresponding critical field is somewhat smaller than BKR and is represented by BKA .

To move the armature 13 by the action of the spring 19, the magnetic remanent field must be brought to a value smaller than BKR. It is assumed that this is achieved in the curve according to FIG. 2 by two negative current pulses N1, Nl . The first of these pulses ΛΊ brings the value B4 to J56. The field value then increases due to the remanence effect according to Bl. Point B 7 is on straight line S 5-0, which corresponds to the larger value of the air gap, because fields B 6 and B 7 are smaller than BKR and consequently armature 13 is active the spring 19 has taken its position remote from the permanent magnet. The second pulse N 2 brings the value along the dashed line from B1 to BS, that is to say almost to the zero value. Because of the remanence, the field then rises along the dashed line to the value B 9 and remains in this state until a new pulse excites the winding 20.

When the winding 20 with further negative pulses were acted upon, the magnetization state of the permanent magnet 12 would still change change easily; but since the negative impulses are relatively weak, the average magnetization becomes of the permanent magnet 12 maintain relatively small values that are significantly smaller than that required for a new tightening of the magnet armature 13 magnetic induction. It should be noted that the decrease in the remanent field of the permanent magnet 12 is known to be achieved just as well by using a weak alternating current can be. Thus, after a certain number of pole changes, the mean magnetic induction would be of the permanent magnet 12 a hysteresis loop of small amplitude around the coordinate zero, point in F i g. 2 run. "

To adjust the armature 13 relative to the permanent magnet 12, the winding 20 is excited by current pulses of suitable polarity. The first impulse, the effect of which in ampere turns is given by Pl in FIG. 2, brings the magnetization from B 9 to # 10, which then falls on B 11 through remanence. A second pulse / '2 brings the magnetization from the value B 11 to the value B12. Since this value is greater than BKA, the magnet armature 13 is attracted against the action of the spring 19. After the end of the pulse / '2, the magnetization falls back to the value β 13, which is still greater than BKA. A third pulse would bring the magnetization of the permanent magnet 12 to the value B 14, which is sufficiently large compared to BKA to ensure that the magnet armature 13 is held securely in the attracted position, even if the valve is exposed to mechanical vibrations.

The coercive force of the permanent magnet 12 is preferably greater than that caused by a current pulse generated in the winding 20, required to attract the core field, but less than four times this field.

The advantage of the arrangement described, which allows a change in the remanent magnetization of the permanent magnet 12 through successive states, lies in the strong reduction in the excitation energy, because the different magnetization points BIO, B12, B14 obtained are in relation to the maximum instantaneous current strength of the pulses. The heating generated by the current flowing through the winding 20 is determined by the effective value of the current. If the control pulses consist of a pole change of an alternating current rectified by a diode, the effective current is equal to half the maximum current. If the control pulses are continuous, the heat output generated in the winding is three to four times smaller than when the winding is supplied with direct current, the value of which is equal to the peak current of a pulse, with iron losses being taken into account. In reality, the gain is significantly greater because, as already explained, the pulses Pl, P2 .... has a weaker amplitude than that which would be required to achieve an increase in magnetization from B 9 to B 14 all at once by means of a direct current.

In order to achieve approximately the same time for the movement of the armature 13 in one direction as in the other direction, a difference in the amplitudes of the pulses P1, P 2, P3 ... and the pulses Nl;

Nl ... provided, the latter being smaller than the first. - ^; · .. ";'■ ·

The valve shown in Fig. 1 has means for generating control pulses from a usual AC power source. For this purpose, one end 50 of the winding 20 becomes immediately connected to terminal 51, while 'the other end 52 of this winding via a diode 54 is fed to terminal 53 and via a diode 56 and a resistor 57 to terminal 55.

Both diodes 54 and 56 are connected so that their polarities are opposite to each other.

To accomplish the attraction of the movable armature 13, the terminals 51 and

53 is connected to a Weclisclstromqucllc, the diode 54 allows the currents of only one polarity through the winding 20. Thus, the pulses Pl, Pl, /'3.ZUr attraction of the armature 13 are generated.

In order to achieve the return path of the armature 13 into the position shown in FIG. 1, the same alternating current source is connected to the terminals 51 and 55. The diode 56 only lets through the opposite currents which generate the pulses / Vl, Nl. The size of these pulses N is smaller than that of the pulses P because of the presence of the resistor 57 in the circuit.

In a variant of the illustrated embodiment, the diode 56 could be omitted, this then, if the demagnetization of the permanent magnet 12 alone by a relatively weak Alternating current is guaranteed, with the resistor 57 for the formation of the demagnetizing current is retained. Of course, the demagnetizing current could be generated by other means: in particular, this electricity could be through Application of a zener diode connected to a nornial Diode · of opposite polarity connected in series, can be generated. Thus the stream would only with a certain polarity these two elements flow through and only then, when the magnitude of the applied alternating voltage is the critical voltage exceeds the zener diode. The advantage of this arrangement is that the pulses for demagnetization can be generated with the help of energy-saving elements and are therefore beneficial for limiting heating of the circuit are.

Of course there is the possibility of other elements to generate the positive and negative Use impulses. These elements could, for example, consist of half-liter transistors or thyristors exist.

The elements for generating positive and negative current pulses for the supply of the winding 20 can preferably form a structural unit with the winding 20. In the case of the in FIG. 1 shown Arrangement, the diodes 54 and 56 and the resistor 57 are embedded in the insulating plastic 58, the serves as a protective cover for the winding 20 at the same time.

A solid, easily assembled unit is thus obtained for the electrical part.

Claims (4)

Patent claims: 1. Solenoid valve mit.einem movable armature in a housing that occupy two switching positions can, an electromagnet, which in the switched-on state on the armature a Exerts force in the direction of the first switching position, and a spring that acts on the armature Exerts force in the direction of the second switching position, characterized in that In the magnetic field of the electromagnet (20) a permanent magnet (12) with variable Remanence is and that the permanent magnet (12) by at least two on the Electromagnet (20) given electrical pulses in one direction in a first magnetic Can be brought into the state in which it pulls the armature (13) into the first switching position, and by at least two electrical pulses applied to the electromagnet (20) in the other direction can be brought into a second magnetic state in which the armature (13) can be moved into the second .Schaltstellung by the spring (19). 2. Valve according to claim 1, characterized in that the winding of the electromagnet (20) is fed with alternating current, the maximum strength of which is smaller than the maximum Current strength of the impulses, which increase the magnetization of the permanent magnet (12) cause: 3. Valve according to claim 1, characterized in that there is a diode (54) for generating of at least one impulse of attraction ; Powered by an alternating current source and furthermore an element (57) fed by the same source for generating a demagnetizing current having. 4. Valve according to claim 3, characterized in that the diode (54) and / or the element (57) form a structural unit with the winding of the electromagnet (20). 1 sheet of drawings