DE1613145B2 - CIRCUIT ARRANGEMENT FOR SUPPLYING A WINDING OF A DC TRAIN MAGNET - Google Patents

Description

of the PTC thermistor an exact reduction of the ignition angle and thus a more precise holding voltage value not reliably given on the magnet. Also with the other known switching arrangements mentioned above the holding voltage value of the magnet cannot be precisely set to a minimum.

The invention is based on the object of providing a circuit arrangement of the type mentioned at the beginning create, in which the disadvantages of the known circuit arrangements are avoided and in a uncomplicated structure and easy handling, the setting of the holding current for the magnet allowed to a minimum.

This object is achieved according to the invention in the circuit arrangement of the type mentioned at the outset solved that the controllable rectifier a series circuit of two capacitors much different Capacitance and a diode are connected in parallel, the capacitor with the larger Capacitance is connected to the diode that the control electrode of the controllable rectifier over \ one. Trigger diode is connected to the junction of the capacitors and that the capacitor with the larger capacity and the diode are bridged by an adjustable resistor.

In such an arrangement, a control pulse of the capacitor with the larger capacitance the controllable rectifier conductive and inr follow the slower voltage rise between the two capacitors the ignition point for the controllable rectifier delayed and additionally the holding voltage by means of the controllable resistor set on the magnet.

• In detail, the circuit arrangement can advantageously be designed so that the capacitance of the capacitors differ by a factor of about 30. Due to the capacity ratio of the Capacitors, the time period for the transition from switch-on excitation to hold excitation is determined. · ·.

Appropriately, a fixed resistor is connected in series with the adjustable resistor and the Series connection of the capacitors and the diode is preceded by a resistor and a Zener diode connected in parallel.

The circuit arrangement according to the invention can be used both with alternating current and with the same direct voltage are supplied. In the latter case, the controllable rectifier ensures that a current flow arises in the two half-periods. However, it is a prerequisite that the supply voltage is not smoothed, d. This means that it drops to zero after each half-wave.

However, it is also possible to use smoothed direct current, i.e. battery current. Then must the respective zero crossing in the controllable rectifier can be forced. This is achieved by that the controllable rectifier with a series connection of a further trigger diode and a third capacitor, the capacity of which is about the same as that of the larger of the other two capacitors, is bridged. The connection point is the second trigger diode and the third Capacitor connected to the output of the winding of the magnet through a resistor.

The circuit arrangement according to the invention has compared to the known circuit arrangements the advantage that the necessary holding current for the magnet by means of the adjustable resistor on Minimum is adjustable. Furthermore, the device according to the invention is so small in size from that they z. B. can be installed directly in the housing of a solenoid valve, as each There is no monitoring or actuation for switching to holding current.

The invention will now be based on the circuit arrangements shown in the drawing, explained. It shows

F i g. 1 shows a circuit arrangement for alternating current or rectified DC voltage,

2 shows a circuit arrangement for battery power.

A switching device is connected to a power source 1, which corresponds to the drawing symbols supplies either alternating current or rectified direct current. A switch 2 is in the current flow inserted for switching the current on and off for a consumer 3, which is a direct current train magnet and to an electromagnetically operated valve, e.g. a two- or three-way solenoid valve, is grown. However, the valve itself and details of the magnet are not shown in the drawing.

Between the switch 2 and the magnet 3 there is a controllable rectifier 4 in the supply line 5 is used, which is also called a thyristor and which is branched off from the line 5 via a Branch line 6 can be influenced. For the purpose of influencing this, the branch line 6 has a smaller one Rectifier diode 7, a resistor 8 connected in series with this, and a trigger diode 9 are switched on.

. In parallel with the resistor 8, a further line section 10 is provided, in which two capacitors 11 and 12 lie. The first condenser 11 in the direction of flow is approximately 30 times larger than the other condenser 12, and between the two capacitors 11 and 12 is a line connection 13 to the branch line 6, which reaches the branch line 6 between the trigger diode 9 and the resistor 8.

The resistance in the line 6 is made controllable in that the constant resistances a variable resistor 14 is connected upstream.

The circuit arrangement described works as follows: After switching on the current via the Switch 1 initially flows through the diode 7 and the capacitors 11 and 12, a charging current surge. During this time, the flow of current through the rectifier 4 is still blocked.

When the voltage across the smaller capacitor 12 exceeds the breakdown voltage of the trigger diode 9 exceeds, then this is conductive, and the rectifier 4 is by the discharge current surge of the Capacitor 12 ignited. The ignition of the rectifier 4 takes place at the moment in which the The supply voltage reaches the level of the breakdown voltage of the trigger diode 9. So that this ignition takes place practically instantaneously, a low-resistance resistor 15 is inserted in front of the diode 7.

During ignition, the passage of current through the rectifier 4 is free and a current can flow to the magnet 3 flow.

A full half-wave runs to the magnet 3, so that it attracts the armature. After the suit the current and voltage should now be reduced, since the magnet is only supposed to hold the armature.

This is done in that the rectifier 4 at the next current zero crossing of the alternating voltage its blocking ability is restored and in the subsequent positive half-wave of the described The process is repeated and the larger capacitor 11 is charged to the peak value of the voltage will.

The voltage in front of the capacitor 11 now rises more slowly, and the ignition point is delayed and less current flows through the branch line 6. The adjustable resistor 14 is used for setting the voltage that is just sufficient for holding operation.

Since it can happen that the input voltage fluctuates and that this fluctuation up to about 10% and cause a voltage fluctuation at the magnet 3 in double the amount could, to avoid this disadvantage, a so-called Zener diode 16 is added to the two capacitors 11 and 12 arranged in parallel. This Zener diode works in conjunction with the low resistance 15 to keep the voltage between the two capacitors 11 and 12 constant to hold, and it is achieved that the ignition timing is no longer due to fluctuations in the input voltage can be influenced. By the size ratio of the two capacitors 11 and 12, the time period for the transition from switch-on excitation to hold excitation can be determined. In the present case the size ratio is 30: 1, but a different ratio can also be used will.

If adaptation to different magnet sizes is desired, the total capacity of the Capacitor 11 can be divided into several individual capacities. By appropriate switching using Step switches or solder bridges can then be set to different time values.

Since there is always a flow of current with only one half-wave, the larger one would occur in the meantime Capacitor 11 partially discharged via resistors 8 and 14. This could possibly mean the other Capacitor 12 is charging too quickly. In order to avoid this, the capacitor 11 a further diode 17 and a further resistor 18 in series with the capacitor 11 switched on, wherein the diode 17 and the resistor 18 are parallel to each other.

In this way it is avoided that a discharge current from the larger capacitor 11 is unwanted drains. The discharge of the capacitor necessary for the function of the circuit arrangement 11 is then reached when switch 2 is switched off.

Finally, there is another parallel to the magnet 3

ίο Diode 19 is provided that the inductance current surge absorbs the magnet winding and as a freewheeling diode, the current flow in the magnet coil also in the sustains a tension-free half-cycle.

In FIG. 2 shows the design of the circuit arrangement in battery operation. Wear it the execution according to FIG. 1 have the same reference numerals.

A third capacitor 20, which is about the same size as the first capacitor 11, a further trigger diode 21, which corresponds to the first 9, and a further resistor 22 for switching delay are added as new parts. The size of the resistor 22 corresponds approximately to that of the resistor 8 and is customized bend C for the desired switching frequency.

This circuit arrangement has the following mode of operation: If switch 2 is closed, it is the rectifier 4 is ignited, and a maximum current flows to the magnet 3. Now the third capacitor 20 charged via resistor 22 and trigger diode 21 ignited. Thereupon flows now Via the trigger diode 21 backwards to the input rectifier 4, a current surge with the opposite Sign due to the charging of the capacitor 20. The current in the rectifier 4 then drops to zero and is blocked in that the rectifier 4 flips over into the blocking state.

After the end of the charging process in the capacitor 11, the current break time is increased to a value dependent on the resistor 15. The pulse time is fixed via the resistor-capacitor combination 22 and 20. In this way, a rectangular current curve is created with relatively long pauses. The voltage drop on the one hand and the size of the pauses on the other hand result _; with direct current operation, after switching on, the lower holding current at the magnet 3.

1 sheet of drawings

Claims (8)

Patent claims: 1. Circuit arrangement for feeding a winding of a direct current train magnet a power source with a reduction in power consumption after the magnet armature has been tightened, in which the winding of the magnet bridged with a diode and a controllable rectifier are connected in series and in the case of the generation of ignition pulses for the controllable Rectifier parallel to this a series connection of at least one resistor and at least a capacitor is arranged and in which the control electrode of the controllable rectifier is connected to a point of this series connection, characterized in that that the controllable rectifier (4) is a series circuit consisting of two capacitors (11, 12) substantially different capacitance and a diode (17) is connected in parallel, the capacitor with the larger capacitance (11) is connected to the diode (17) that the control electrode the controllable rectifier (4) via a trigger diode (9) with the junction of the Capacitors (11, 12) is connected and that the capacitor with the larger capacitance (11) and the diode (17) are bridged by a controllable resistor (14). 2. Circuit arrangement according to claim 1, characterized in that the capacities of the Capacitors (11, 12) differ by a factor of about 30. 3. Circuit arrangement according to claim 1 or 2, characterized in that a fixed resistor (8) is connected in series _{with the Regelba 7 Ren resistor (14).} 4. Circuit arrangement according to one of claims 1 to 3, characterized in that the Diode (17) a resistor (18) is connected in parallel. 5. Circuit arrangement according to one of claims 1 to 4, characterized in that the A resistor (15) is connected upstream of the capacitors (11, 12) and the diode (17) connected in series and a Zener diode (16) is connected in parallel. 6. Circuit arrangement according to one of claims 1 to 5 for the use of alternating current or pulsating direct current as supply current, characterized in that the series connection of the capacitors (11, 12) and the A further diode (7) is connected upstream of the diode (17) in a known manner. 7. Circuit arrangement according to one of the. Claims 1 to 5 for the use of direct current as a supply current, characterized in that the controllable rectifier (4) is connected in series from a further trigger diode '(21) and a third capacitor (20), whose; capacity is about as large as that of the larger of the other two capacitors that is bridged. 8. Circuit arrangement according to claim 7, · characterized; that the connection point the second trigger diode (21) and the third capacitor (20) via a resistor (22) connected to the output of the winding of the magnet. The invention relates to a circuit arrangement for feeding a winding of a direct current train magnet from a power source with a reduction in power consumption after the magnet armature has been tightened, in which the winding of the magnet bridged with a diode and a controllable rectifier are connected in series and in the case of the generation of ignition pulses for the controllable Rectifier parallel to this a series connection ίο from at least one resistance and at least a capacitor is arranged and in which the control electrode of the controllable rectifier with is connected to one point of this series circuit. Such a circuit arrangement is from the German J5 see Auslegeschrift 1 215 887 known. With conventional direct current magnets, a multiple of the current is required for the pull-in excitation the holding excitation is required. As a rule, however, the necessary holding current is only about a tenth of the starting current. Since with DC solenoids the current consumption is independent from the armature position, the solenoid must correspond to the required when tightening Performance can be dimensioned. For this reason it is important after tightening the armature to reduce the current consumption of the electromagnet. ....... - In this context, a control unit for a controllable rectifier (thyristor) has become known, as a controlled converter to supply a load from an AC voltage source serves. By means of this control unit, the ■ Ignition pulses for the controllable rectifier in their Phase shifted. The main parts of the control unit are parallel to the controllable one Series circuit made up of a capacitor, an adjustable resistor and a rectifier Diode and also one between the one capacitor plate and the control electrode of the controllable Shokley diode arranged in a rectifier .. · (Hoffmann, A. and Stocker, K., Thyristor-Handbuch, Berlin and Erlangen, 1965, pp. 130 and 131).
In a further known switching arrangement, when supplying inductive loads from a DC voltage source via a controllable rectifier, special precautions must be taken for deleting the controllable rectifier; be fenced. In the known switching arrangement, these consist in that a series circuit of a capacitor and another controllable rectifier is connected in parallel to the controllable rectifier, the junction of the TC condenser and the second controllable rectifier being connected to the output of the inductive consumer via a resistor (AEG messages , Vol. 56, 1966, pp. 117 to 121). Furthermore, a device would be used to shorten the switch-on time of a pulsing via a thyristor DC voltage connected inductive load proposed in which an i? C circuit contains a PTC resistor whose change in resistance is necessary to reduce the firing angle of the thyristor necessary increase in the recharging time of the capacitor (patent 1,270,152). With this device is due to tolerances in the PTC thermistor itself and especially as a result of deviations and heating irregularities