DE19725317A1 - Control of dc actuated electro magnetic valves - Google Patents

Abstract

The electro magnetically 14 actuated valve 12 is operated by opening and closing a switch 18 that is located between an ac supply 16 and a rectifier circuit 20 . The rectifier is connected to the actuator by a control circuit 30 that provides fast turn off . This is obtained by providing a short circuit dependent upon the switch off induction voltage.

Description

The invention relates to a circuit arrangement for Control of a DC-operated Solenoid valves with the in the preamble of claim 1 mentioned features.

State of the art

Circuit arrangements of the generic type are known. For example, in hydraulic or Pneumatic applications switching valves used Actuating means connectable with DC voltage Is electromagnet. By applying the electroma This will build up with the DC voltage end magnetic field to perform a switching operation utilized. When the supply voltage is switched off the electromagnet off, so that the switching action back is commonly feasible. Operable with DC voltage Electromagnets offer alternating voltage operable electromagnets the advantage that a simpler construction, for example due to elimination a short-circuit ring is possible. However, because licher at possible application sites as a supplier AC voltage is available is known, the solenoid valves with a Rectifier circuit to provide the anlie  AC voltage to operate the solenoid valve les rectified.

When the electromagnet is switched off, an inductor tion current induced by the rectifier circuit is dismantled. Since the rectifier scarf causes only a slight voltage drop, is the period within which a residual magnetisie tion of the electromagnet is present, relatively long. This delays the magnetic vein from falling off tiles after the actual switch-off time since a tightening force of the electromagnet in approximately proportions tional one flowing through the electromagnet Current is, so that an exact switching behavior of the Solenoid valves is impaired.

The invention is therefore based on the object Suit circuit of the generic type ben, which is simple and by means of one Switching characteristics of a solenoid valve can be optimized is.

According to the invention, this task is accomplished with a scarf arrangement with the note mentioned in claim 1 paint solved. The fact that between the rectifier circuit and an electromagnetic actuator means of the solenoid valve a control circuit is switched when the AC voltage is switched off voltage source, the rectifier circuit from the actuation detergent and depending on an Ab switching induction voltage of the actuating means ser over a voltage-dependent resistor briefly  closes, is advantageously possible in the electro magnetic actuators stored energy after switching off the AC voltage inside half the shortest time, so that the time between switching off the AC voltage supply and the falling of the solenoid valve drastically reduced is decorated. Through the related improvement the switching characteristics can be switching operations by means of the circuit arrangement according to the invention having solenoid valves very precisely, that is, execute very precisely. By the invention Circuit arrangement can be with DC voltage actuatable solenoid valves in a simple manner Integrate systems with AC power supply, without complex adjustments being necessary.

Through the circuit arrangement according to the invention it is possible to operate electrical with DC voltage use magnets in solenoid valves to switch to achieve characteristics that otherwise only from the cost-intensive, operated with AC voltage Bare electromagnets can be achieved.

Advantageous refinements of the invention result derive from the characteristic mentioned in the subclaims len.

drawings

The invention is described below in exemplary embodiment len with reference to the accompanying drawings tert. Show it:  

Figures 1 and 2 different variants of a circuit arrangement for controlling a solenoid valve.

Fig. 3 shows a concrete circuit of a switching means of the circuit arrangement according to FIG. 1 and

Fig. 4 to 6 voltage and current waveforms of the circuit arrangement according to the invention.

Description of the embodiments

Fig. 1 shows a circuit arrangement 10 for controlling a solenoid valve at the 12th The solenoid valve 12 comprises a DC magnet 14 , which forms an actuating means of the solenoid valve 12 . The DC magnet 14 can be acted upon by an AC voltage source 16 with a supply voltage. The AC voltage source 16 can be switched on or off by means of a switching means 18 . To rectify the AC voltage supplied by the AC voltage source 16 , a rectifier circuit 20 of diodes D ₁ , D ₂ , D ₃ and D ₄ connected in a bridge circuit is provided. Outputs 22 and 24 of the rectifier circuit 20 are connected to inputs 26 and 28 of a control circuit 30 , the outputs 32 and 34, respectively, are connected to the DC magnet 14 .

The control circuit 30 comprises a switching means 36 which is connected on the one hand to the input 28 and on the other hand to the output 34 . The switching means 36 can be controlled via a control unit 38 which is connected between the inputs 26 and 28 . Furthermore, a voltage-dependent resistor 40 is switched between the outputs 32 and 34 of the control circuit 30 .

The circuit arrangement 10 shown in FIG. 1 performs the following function:

It is assumed that the solenoid valve 12 is part of a pneumatic or hydraulic application, a pneumatic or hydraulic connection line, for example, to be closed or opened by means of the solenoid valve 12 . If the solenoid valve 12 is to switch, the switching means 18 is closed via a corresponding control signal, so that the AC voltage source 16 is connected to the rectifier circuit 20 . This bridge rectifier, known per se, supplies a direct voltage which is present at the inputs 26 and 28 of the control circuit 30 . The presence of the DC voltage is detected via the control unit 38 , so that the switching means 36 is closed. As a result, the DC voltage is applied to the outputs 32 and 34 of the circuit arrangement 30 and thus to the DC magnet 14 of the solenoid valve 12 . According to the magnetic field thus created, this acts as an actuating means for the solenoid valve 12 . The voltage-dependent resistor 40 , which is designed, for example, as a varistor, has a threshold voltage which is above the operating voltage of the direct current magnet 14 . As a result, this is high-resistance in normal operation.

If the solenoid valve 12 change its switching state, the switching means 18 is opened via a corresponding signaling, so that the alternating voltage source 16 is separated from the rectifier circuit 20 . About the control unit 38 it is recognized that between the inputs 26 and 28 of the control circuit 30 and thus between the outputs 22 and 24 of the rectifier circuit 20 there is no longer a DC voltage. The control unit 38 is designed so that in this case the switching means 36 opens the connection between the input 28 and output 34 of the control circuit 30 . The DC magnet 14 is thus short-circuited via the voltage-dependent resistor 40 .

As is known, when a DC magnet 14 is switched off, a switch-off induction current occurs as a result of the dissipation of a stored magnetic energy, which leads to the generation of an induction voltage. This induction voltage lies above the threshold voltage of the voltage-dependent resistor, so that it becomes low-resistance. As a result, the DC magnet 14 is short-circuited. The magnetic energy stored in the direct current magnet 14 can thus be rapidly dissipated via a high induction voltage. This has the advantage that the magnetic field of the DC magnet 14 is reduced within a very short time, so that the Ma gnetventil 12 changes its switching position very quickly after opening the switching means 18 .

The supply voltage U of the AC voltage source 16 can be, for example, 230 V at 50 Hz or 110 V at 60 Hz. The switching threshold of the voltage-dependent resistor 40 is above the supply voltage and is, for example, 300 V.

In Fig. 2, the circuit arrangement 10 is shown in a further embodiment, the same parts as in Fig. 1 see with the same reference numerals and are not explained again.

According to the embodiment variant shown in FIG. 2, the switching means 36 is bridged by the voltage-dependent resistor 40 . The remaining components of the circuit arrangement 10 are unchanged from the exemplary embodiment shown in FIG. 1. This arrangement also ensures that when the DC magnet 14 is switched off, a very high switch-off induction voltage can drop across the voltage-dependent resistor 40 , so that the magnetic field of the DC magnet 14 is broken down very quickly. In this case, the shutdown induction current also flows through the rectifier circuit, but the much larger voltage drop, which leads to the rapid reduction of the magnetic field, occurs via the resistor 40 .

FIG. 3 shows a specific circuit variant of the control circuit 30 according to FIG. 1. The switching element 36 is ausgebil Det as a MOSFET transistor, the gate terminal is connected to a node K _1, which is connected on the one hand via a resistor R ₁ to the input 26 and on the other hand via a surge diode 42 to the input 28 . The voltage-dependent resistor 40 is realized by an overvoltage diode 44 and a diode 46 , the cathode of which is connected to the overvoltage diode 44 and the anode of which is connected to the output 34 of the control circuit 30 .

When the switching means 18 is switched on, the voltage provided by the rectifier voltage 20 is present at the node K ₁ and thus at the gate of the MOSFET 36 . As a result, the MOSFET 36 is turned on , and the input 28 is connected to the output 34 of the circuit arrangement 30 . The overvoltage diodes 42 and 44 are blocked.

After opening the switching means 18 flows, already explained with reference to FIGS . 1 and 2, from switching induction current of the DC magnet 14th The resulting induction voltage here is above the threshold voltage of the overvoltage diodes 42 and 44 , respectively, so that they become conductive. The gate-source voltage of the MOSFET 36 is hereby pulled to zero, so that the MOSFET 36 opens. The DC magnet 14 connected to the outputs 32 and 34 of the control circuit 30 is thus short-circuited via the overvoltage diode 44 and the diode 46 , so that a high shutdown induction current can flow, which leads to the rapid breakdown of the magnetic field and thus to the rapid switching of the solenoid valve 12 leads.

Referring to Figs. 4, 5 and 6 is intended to be illustrated Schaltcharak 10 teristik the circuit arrangement. FIG. 4 shows the AC voltage profile of the AC voltage source 16 , while FIG. 6 shows the induction current I of the DC magnet 14 . For comparison, the course of the induction current I in the prior art is shown in FIG. 5, that is, without the control circuit 30 . The ripple of the induction current I results from the residual ripple of the rectified AC voltage of the AC voltage source 16 via the rectifier circuit 20th

The switching means 18 is opened at time t ₁ ( FIG. 1). As a result, the supply voltage U is switched off according to FIG. 4. Due to the stored magnetic energy in the DC magnet 14 , the shutdown induction current I is set, which - as illustrated in FIG. 6 - drops to a negligible value close to zero by the time t ₂ . The time period t ₂ -t ₁ is, for example, 10 ms. This large gradient of the switch-off induction current I is realized by the short-circuiting of the DC magnet 14, explained with reference to the previous figures, via the control circuit 30 . On the basis of a comparison with the characteristic curve of the shutdown induction current I shown in FIG. 5 without the control circuit 30 , it becomes clear that there the induction voltage across the rectifier circuit 20 drops slowly in relation, so that a relatively small gradient of the shutdown induction current I. given is. The shutdown induction current I only reaches a negligible value at time t ₃ . The time period t ₃ -t ₁ is, for example, 40 ms. It is therefore clear that by means of the control circuit 30 a drop in the shutdown induction current I which is approximately 4 times faster is achieved. Correspondingly faster, the magnetic field of the DC magnet 14 is broken down, so that the solenoid valve 12 changes its switching state faster by this factor.

With simple means, an optimization of the switching characteristics of the solenoid valve 12 can be achieved. The electronics of the circuit arrangement 10 can very advantageously be integrated into a housing of the solenoid valve 12 . Thus, a standardized magnetic valve 12 , which can be operated with direct voltage, can be used in AC voltage applications without additional effort.

Claims (8)

1. Circuit arrangement for controlling a solenoid valve which can be actuated with direct voltage, the solenoid valve being connectable via a rectifier circuit to an alternating voltage source, and a switching means connecting or disconnecting the alternating voltage source to the rectifier circuit, characterized in that between the rectifier circuit ( 20 ) and an electromagnetic magnet Actuating means ( 14 ) of the solenoid valve ( 12 ) is connected to a control circuit ( 30 ) which, when the alternating voltage source ( 16 ) is switched off, separates the rectifier circuit ( 20 ) from the actuating means ( 14 ) and as a function of a switching-off induction voltage of the actuating means ( 14 ) this shorts. 2. Circuit arrangement according to claim 1, characterized in that the control circuit ( 30 ) has a switching means ( 36 ) which is connected on the one hand to the rectifier circuit ( 20 ) and on the other hand to the actuating means ( 14 ). 3. Circuit arrangement according to one of the preceding claims, characterized in that the Schaltmit tel ( 36 ) via a control unit ( 38 ) can be controlled, which is connected to outputs ( 22 , 24 ) of the rectifier circuit ( 20 ), and which has a shutdown device the AC voltage source ( 16 ) is detected. 4. Circuit arrangement according to one of the preceding claims, characterized in that the Schaltmit tel ( 36 ) is a MOSFET transistor or bipolar transistor. 5. Circuit arrangement according to one of the preceding claims, characterized in that the actuating means ( 14 ) is a direct current magnet to which a voltage-dependent component which changes its resistance value is connected in parallel. 6. Circuit arrangement according to claim 5, characterized in that the voltage-dependent its resistance value changing component is a varistor ( 40 ) whose threshold voltage is above an operating voltage of the DC magnet ( 14 ). 7. Circuit arrangement according to claim 5, characterized in that the voltage-dependent its resistance value changing component is a Überspannungsdi ode ( 44 ) whose ignition voltage is above an operating voltage of the DC magnet ( 14 ). 8. Circuit arrangement according to one of claims 1 to 4 and 6 to 7, characterized in that the voltage depending on its resistance value changing component is connected in parallel to the switching means ( 36 ).