DE2316865C3 - Arrangement for switching a double electromagnet - Google Patents

Description

The invention relates to an arrangement for switching a double electromagnet with opposing individual magnets and a common connection ker, which is used to turn the armature from a first to a second layer through the coil of the second Individual magnets flowing current increases and the first individual magnet switches off and the after Turning the armature switches the coils of both individual magnets back in series, especially for Control of a two-way valve.

Such an arrangement is from DE-PS 3 04 970 known.

65 State of the art

In the arrangement known from DE-PS 3 04 970 wjrH Her magnetism of one meter strengthened and that of the other weakened. Here it is provided in detail that the coil of the to strengthening magnet directly to the operating voltage, the coil of the magnet to be weakened is short-circuited or switched off and that after being turned over of the armature, both coils are switched back in series.

Apart from the strong contact load of the open circuit specified in the above-mentioned patent mechanical Umschaltkoniakte, is to be noted as a disadvantage that when connecting the two Coils at the end of the armature movement an undefined state occurs. This state results from the Inability of the re-switched coil to immediately conduct a current and thus the current in the already energized coil to maintain. Do you want a double magnet with short turnaround times and build safe end positions of the anchor, the above-mentioned device must be modified.

For the problems that occur when switching off a coil is from the Siemens magazine, 38th year, 1964, No. 11, pp. 817 to 819, known as the solution, thereby increasing the decay time of the magnetic field of a coil shorten that parallel to the coil a series circuit consisting of a diode and a Zener diode is switched; vgL the Fig.5c together with the associated one Description.

From DE-PS 3 37 580 it is known for an alternating current magnet when interconnecting two coils after tightening the armature to avoid the de-energized state by having a Resistance is provided which acts as a damping resistor in the short-circuit circuit of the connected coil during the bridging time

task

The invention specified in claim 1 is based on the object of an arrangement for switching of double magnets, which causes quick turnaround times of the armature and also in the case of the Interconnection of the coils after switching over the armature no currentless state occurs

This object is achieved by the advantageous and advantageous arrangement characterized in claim 1 Appropriate refinements and developments can be found in the subclaims.

advantages

The arrangement according to the invention results in very short turnover times of the double magnets The armature briefly reaches another position without the armature being in the respective end position occupies If such a double magnet is used to control a two-way valve, it shows that the valve disc remains in the desired position without bruises after switching

Description of an embodiment of the invention

An embodiment of the invention is shown schematically in the drawing and is shown in The following is explained in more detail It shows

F i g. 1 an overview circuit diagram of the double magnet with mechanical contacts,

F i g. 2 shows a block diagram of the double magnet according to P i g. 1 with electronic switching means and

F i g. 3 a block diagram of a further circuit possibility of the double magnet.

In FIG. 1 with A and B are two coils one

Double magnets denote a common armature for both coils. The coil A is connected from a positive operating voltage U _B via a break contact 1 and a diode 2 to the coil B , which is connected to the zero potential via a further break contact 3. The normally closed contact I is part of a probe b having yet a working contact 2i, and the break contact 3 is part of a button A, the parallel also still has a normally open contact 22 to the coil A and the break contact 1 is a diode 4, whose anode further A Zener diode 5 is connected to the connection point of the coil A with the normally closed contact 1. There is also a diode 6 parallel to the coil B and the normally closed contact 3, the anode of which is also connected to the connection point of the coil B with the normally closed contact 3 via a Zener diode 7 and 7 have approximately a breakdown voltage which corresponds to five to six times the operating voltage

The button b can connect the operating voltage Ug to the coil B , and the button a can apply the zero potential directly to the connection line between the diode 2 and the normally closed contact 1.

The switching of the armature from one position to the other will be described below, it being assumed as an initial state, that the anchor on the ropes of the coil A, and have current flowing through both coils A and B. Despite the flow of current through the coils, the armature remains in this position because it increases the inductance of coil A. Due to the series connection of coils A and B , only a small current flows in it, which is sufficient to hold the armature and is therefore called the holding current. To switch the armature to the side of coil B , pushbutton b is pressed.By the now closed normally open contact 21, coil B is directly connected to the operating voltage, and the ampere turns of coil B are doubled, which results in a large increase in the magnetic tensile force Da In addition, the current in coil B does not rise from the value zero, but rather from the holding current, resulting in a very short pull-in time if the magnetic field of coil A is rapidly reduced. The normally closed contact 1 of the button b has been opened, and the energy of the coil A builds up via the diode 4 and the Zener diode 5, which has a high breakdown voltage. When the armature has reached its new position on the coil B , the button b is released again, and the normally closed contact 1 closes and the normally open contact 21 opens so that the low holding current flows again in the coil B by connecting the coil A upstream

So that the upstream connection of coil A does not result in a currentless state because the current in coil A can only build up slowly from zero, the diode 6 is connected in parallel to break contact 3 and coil ß. Through this diode 6, the pick-up current of coil B can continue flow and decrease, until the rising current in the coil A further current flow in both coils ensured by the slow build-up of the magnetic force of the coil A, the re-flow of the current in the coil B and increasing the inductance of the coil B by the applied armature a secure fit of the anchor in its new position is guaranteed.

If the armature is to rest on the coil A again, the button a is to be pressed, whereby the coil A is connected directly to the operating voltage via the normally open contact 22 and the coil B is separated from it by opening the normally closed contact 3. The rest of the process is analogous to that described above.

The arrangement for switching the double magnet with the coils A and B is shown in FIG

electronic switching means shown. The same designations have been chosen for the same parts as in FIG. 1. The normally closed contact 1 consists of a transistor 8, the collector of which is connected to the coil A and the emitter of which is connected to the diode 2. The base is connected via a resistor 9 to the collector and via a diode 10 to the input of the normally open contact 21, which is formed from an inverting amplifier stage 11 and a subsequent transistor 12 and whose control input is denoted by 23. At the control entrance

is the button b mentioned in Fig. 1 or control electronics. The transistor 12 can fly the operating voltage t / s directly to the coil. This structure of the normally open contact 21 was chosen in order to be able to effect switching through with weak signals at the control input 23.

The normally open contact 22 and the normally closed contact 3 are constructed in the same way as those just described. The normally closed contact 3 consists of a transistor 13, the collector of which is connected to the coil B and the emitter of which is connected to zero potential. A Zener diode 14 with a low breakdown voltage is inserted into the base line in order to safely switch off the transistor 13. The transistor is turned on via a resistor 15, which lies between the collector and the Zener diode 14, and switched off via a diode 16 which is connected from the Zener diode 14 to the output of the normally open contact 22. The normally open contact 22 consists of an inverting amplifier stage 17 and a subsequent transistor 18 which can connect the coil A directly to the zero potential via the normally closed contact 1. The control input is labeled 24.

It is assumed that the armature is on the side of coil B and that the holding current flows through both coils. For this purpose, there is a logic one signal at the control inputs 23 and 24 of the amplifier stages 11 and 17, which is inverted by them so that the transistors 12 and 18, respectively, receive a zero signal and are switched off. So that the armature switches to its other position, a logic zero signal is to be applied to the control input 24 of the amplifier 17, whereby the transistor 18 switches through and connects the coil A via the transistor 8 directly to zero potential. The current through coil A rises rapidly to the pull-in current, and the armature is pulled to the coil A side. At the same time, the transistor 13 is also blocked via the diode 16 with the zero potential of the transistor 18 switched through. The Zener diode 14 ensures that the residual voltages at the diode 16 and the transistor 18 are balanced, as has already been mentioned. The coil B is switched off and can convert its stored energy via the diode 6 and the Zener diode 7.

Once the armature has reached its new position, the switched off coil B is again connected in series with the energized coil A so that the lower holding current is set and the power consumption is reduced.

For this purpose, the zero signal at the control input 24 of the amplifier 17 is changed back to a one signal.

As a result, the transistor 18 blocks and puts the coil A in

Row to coil B. Current can now flow into the base of transistor 13 via resistor 15 and control it to be permeable. As long as coil B takes up

A current flows through it, the current in coil A must be able to continue to flow via a different path. This path goes via the switched transistor 8. The diode 4 back to the coil A. As the increased current of the coil A decays over this path, the current through the coil B increases until a Current transfer takes place and the series circuit is closed.

If the armature is to assume the position on coil B again , a logic zero signal must be applied to control input 23 of amplifier 11. This switchover then takes place analogously to the process described above.

In Figure 3, a further circuit possibility of the double magnet is indicated. The basic structure is like the one already described, only the current path for the current of the switched-on coil, if the previously de-energized coil is connected in series, is different. If the coil A is switched on and if the previously switched off coil B is connected in series after switching the armature, the current of coil A flows through a Zener diode 19 parallel to coil B. This Zener diode 19 has a breakdown voltage slightly above half the operating voltage , so that after the increase in the current through the coil E, the Zener diode 19 blocks again and the current flows through the series connection of the two coils.

A Zener diode 20 is also parallel to coil A and takes over the current of coil θ until the holding current has been set in this coil after the currentless coil A has been connected upstream.

A positive operating voltage U _B must be applied to the specified circuits, the diodes must be used as shown in the figures, and NPN transistors must be used. If a negative operating voltage is available, the polarity of the diodes must be reversed and PNP transistors must be used.

For this purpose 3 sheets of drawings

Claims (4)

Patent claims: 1. Arrangement for switching a double electromagnet with opposing individual magnets and a common armature, which increases the current flowing through the coil of the second individual magnet to turn the armature from a first to a second position and switches off the first individual magnet and which, after turning over the Armature switches the coils of both individual magnets back in series, in particular for controlling a two-way valve, characterized in that a series circuit consisting of a diode (4, 6) and a Zener diode (5, 7) parallel to its coil to reduce the magnetic field of the disconnected individual magnet is switched, and that switching means are provided which, after the coils (A, B) are connected in series, allow the increased current flow in the energized coil to decay until the re-switched coil has almost reached its holding current and the further current flow in both coils guaranteed 2. Arrangement according to claim 1, characterized in that the switching means consists of one break contact connected in series to each coil (A or B) (1 or 3) of a button (a or b) and a diode (4 or 6) connected in parallel to the coil and normally closed contact. 3. Arrangement according to claim 1 and 2, characterized in that the normally closed contacts (1, 3) from Transistors (8 or 13) are formed, the bases of which on the one hand via a resistor (9 or 15) with their collectors and on the other hand via a diode (10 or 16) with their associated Control input (23,24) are connected. 4. Arrangement according to claim 1, characterized in that the switching means consist of Zener diodes (19, 20) connected in parallel to the coils (A, B) , so that the current of the energized coil decays via the Zener diode lying parallel to the connected coil, and that the Zener diodes (19, 20) have a breakdown voltage slightly above half the operating voltage (Ub) , so that after the increase in the current in the connected coil, the Zener diode lying parallel to it blocks and the current flows through the series connection of the two coils 50