DE904091C - Mechanical switching converter - Google Patents

Description

Mechanical switched-mode converter The invention relates to a mechanical converter Switching converter, the contacts of which are electromagnetic against a restoring force are closed and held and with switching throttles for generating on and Switch-off current stages are in series, with a winding through which the contact current flows (Main current winding) and with a special control circuit. According to the invention is the main current winding of the magnet system as its only control winding in the control circuit included. This saves an additional control winding, while the main current winding is usually already present for the reason, so that the contact pressure is automatically increased by them at high amperage. The aforementioned special control circuit can in particular serve in a arbitrarily chosen moment with positively directed, d. H. in the direction of the prescribed Current flow driving the switch-on voltage, but before the switch-on level the following increase in the contact current, the tightening force required to close the contacts and during the drop in contact current preceding the switch-off stage, a to produce sufficient magnetic force to hold.

FIGS. R to 3 contain schematic representations of exemplary embodiments of the invention and a diagram to explain its mode of operation. The better one For the sake of clarity, single-pole arrangements are shown, multi-pole arrangements can be made from them be developed in a manner known per se. The same parts are in all figures provided with the same reference numbers, According to Fig. I are a secondary winding i a feed transformer, a switching inductor 2 and a contact device 3 with the magnet coil 4 through which the main current flows, connected to form a deformation arrangement, their direct current side from a consumer 5 with a series smoothing choke 6 and load switch 7 consists. A base load 8 prevents when the switch is open 7 the drop in direct current below a prescribed minimum value.

A switch on the series circuit of the switching throttle is used to close the contacts 2 and the contact device 3 connected control circuit containing a DC or AC voltage source, e.g. B. a battery g, a controlled valve io, e.g. B. a discharge vessel with control grid, and a setting resistor i i. A surge current generated in this control circuit flows through the main current winding q. and causes the contacts to close. The requirements for activation but are only given when the switch-on voltage, which is applied to the series connection the switching throttle: 2 and the contact device 3 occurs, is positively directed, d. H. so that it is able to flow a current in the prescribed direction across the contacts and through the DC circuit. The voltage of the battery For this purpose, 9 is dimensioned so that it is slightly higher than the ignition voltage of the control valve OK. The ignition moment itself can, as long as the aforementioned requirements are given, arbitrarily by a controllable grid control of a type known per se selected and thus the degree of modulation of the deformation arrangement can be changed. Instead of the controlled valve io, one of the valves shown in FIGS. I a and i b can be used Arrangements between the connection points f and g may be switched on as an alternative. According to FIG. 1a, this is a series connection of an uncontrolled Valve 12 and a controllable DC voltage source 13, which has a voltage in the reverse direction of the valve 12 supplies. The control range of this equivalent arrangement is smaller, he includes only the time segment of the rise of the switch-on voltage. This limitation does not apply, however, to the arrangement according to Fig. i b. It consists of a transducer 14 with the magnetization characteristic inclined to the flux axis in the unsaturated area, its working winding 16 connected in series with an uncontrolled valve 15 and whose control winding 17 is supplied with direct current from any voltage source, z. B. a battery 18, via a stabilizing throttle i9 and a regulating resistor 2o is excited so that the initial state of the transistor in the unsaturated area lies. With such a valve throttle arrangement, it is known that one-sided Directed current surges are generated, the time of which is within an alternating voltage half-wave can be selected as required by regulating the direct current bias.

To generate and adapt the on and off stages, in addition to the main winding 22, various auxiliary windings and auxiliary circuits are provided for the magnetic core 21 of the switching inductor 2, some of which are shown in FIG. By means of a so-called stretching circuit 23, which is connected to the auxiliary winding 24 and, for example, in the simplest case consists of a capacitor 25 and a resistor 26, the step current as horizontal as possible is achieved in a manner known per se. A bias circuit 27 supplies a constant portion of the bias for the switch-off stage and consists of the series connection of an auxiliary winding 28 with a stabilizing choke 30 and an adjustable resistor 31 connected to any direct current source. A battery 29, for example, serves as a direct current source "ation, which enables the step current to be adjusted to zero, is supplied by a further auxiliary circuit 32, which can be connected to a tap, preferably in the middle, of the main winding z2 of the switching inductor 2, and contains the series connection of a setting resistor 33 and an uncontrolled valve 3q .. Its other connection point can either, as shown, be on the direct current circuit point b or also on point k2 level control works. The task of this valve is to ensure that, with extensive partial modulation, the switching throttle is not saturated prematurely under the influence of the positive switch-on voltage in the direction of the expected current, but remains in the opposite saturation state until the control command for the contact closure is given, see above that after the contact has closed, at least: a part of the switch-on stage must be run through before the main current can begin to rise. An arrangement can be used to influence the switch-on level.

Such a bias arrangement, which by automatic adjustment the switch-on bias in the entire modulation range to meet all requirements is fair, contains an auxiliary circuit 42 with a special auxiliary winding 35 of the switching inductor and a setting resistor 43 and is controlled by the switch-on voltage fed. The timely onset of this portion of the premagnetization can together with the control circuit for the contact closure by the discharge valve io or one of its replacement devices or by a special discharge valve or a corresponding substitute device can be controlled. That kind of control has the consequence (with the assistance of the auxiliary winding 36 explained later) that the remagnetization of the switching choke before switching on at the same instant begins like the increase in the control current for the contact closure. The instant of switch-on falls as a result, since the exciting current in the solenoid q. only except for the contact closure required value must increase, in any case during the time the switch-on level is running.

In addition to the voltage-dependent one supplied by the auxiliary winding 35 The part of the switch-on bias is still constant during the switch-on stage Part for the switch-on bias required, for which another auxiliary winding 36 is provided because the DC excitation supplied by the auxiliary winding 28 is in the wrong direction for switching on. It is therefore necessary temporarily during the period of time that is considered for the contact closure a resulting flux for the constant portion of the premagnetization to create, which has the opposite direction as when switching off. That can z. B. done in such a way that the constant switch-off bias (Winding 28) with the help of winding 36 a current pulse of approximately constant Height and opposite magnetizing direction is superimposed. To this end receives, for example, the auxiliary winding 36 from an AC voltage source a pulse generator (transductor) 4q., premagnetized up to above the saturation knee, whose working winding q: 6 is connected in series with a valve 45, short-term Current surges and is switched in such a way that they have an oppositely magnetizing effect like the direct current in winding 2 @ 8. In Fig. I d is the superposition of the two in the auxiliary windings 28 and 36 effective excitations as a function of time t shown. The excitation in winding 28 is represented by a parallel to the zero line below this at a distance VA-, corresponding to the constant Share of switch-off bias. The switch-on bias VE- has almost rectangular waveform, because the impulse current after entering the transductor qq. remains roughly constant in the unsaturated state. By superimposing the two Magnetizations results in a resulting magnetization that remains the same Components of the premagnetization both for switching off and for switching on contains, corresponding to a current i "- according to the solid line in Fig. i d Passive and negative values of i "_, taken absolutely, can be different from each other be. The auxiliary circuit of the winding 36 is advantageous at points g and k2 or b (Fig. i) connected. Then the phase position of the positive impulses is given by the controlled ignition timing of the discharge valve io. The winding 47 of the transductor 44. is via a stabilizing choke 5o and a setting resistor 51 excited from any DC voltage source. It is according to Fig. I c, for example also connected to the battery 29.

Also to be mentioned are the uncontrolled valves 48 and 49 to optionally supplement the control circuit of the winding q. or the auxiliary circuit of the winding 35 for the purpose of preventing currents in the wrong direction.

The DC-side end of the auxiliary circuit of the winding 35 can be connected to point k2 instead of point b. From this change results by omitting the current path leading through the resistor i i the arrangement according to Fig.2, in which the entire control current used to close the contact also for voltage-dependent switch-on bias in the auxiliary winding 35 use finds. In addition (FIG. 2 also shows this) the control winding q. instead of on the direct current side of the series connection of switching inductor and contact device also be arranged on their alternating current side.

Among other things, it is also possible with the help or main current winding q. to control the switch-off process automatically so that the contact separation during the switch-off level begins. For this purpose, the from the discharge vessel io or the corresponding Replacement devices for switching on released control current after termination of the Switch-on level up to the start of the switch-off level by selecting the appropriate from the battery 9 or another suitable voltage source resulting voltage and the ohmic resistance in the control circuit is above the dropout value of the magnet system is held. When the switch-off stage starts, due to the voltage appearing at the switching throttle at the same time, the Discharge vessel blocked. Only then does the control current disappear from the winding q. completely, so that the contacts after falling below the drop value of the magnet system open during the switch-off stage.

The bias devices described in connection with FIG enable a practically complete adjustment of the stage current down to zero and thus meet the highest demands. However, for lower demands A satisfactory operation even with simpler means (at least in a limited way Modulation range) can be achieved. For this purpose, some exemplary embodiments are given below described.

According to Fig. 3a is except for the stretching circle with the winding 24 only a single auxiliary circuit 37 is provided with a winding 38, which consists of an alternating voltage source is fed via a stabilizing and adjusting throttle 39. In parallel with the Contact device 3 is arranged a bypass which, as is known, is an ohmic one Resistance q: o or instead a known series-parallel connection of Contains resistors and capacitors. By correct balancing of the byway and the auxiliary circles becomes a resulting bias of alternating direction achieved with such a phase position and height that to the through the control current in the main current winding q. specified times. for contact closure and opening also the for Protection of the contacts necessary or switch-off stage is currently running.

According to Fig. 3 b, instead of a bypass, a to the series connection the feeding Transformatorwicklun.g i and the main winding 22 of the switching inductor 2 connected shunt circuit with a Zi "irk resistance .I1 provided through whose Correct matching produces a similar effect as with the arrangement according to Fig. 3-a. In both arrangements, the main current winding d of the N-Z magnet system be connected and controlled either according to FIG. 1 or according to FIG.

The arrangement according to FIG. 3 b can be improved even further as a result, that the circle 38 is charged with finite trapezoidal instead of sinusoidal alternating current is, for example, from a transductor circuit with two oppositely biased Saturation chokes. This Trapezstroin supplies the constant proportions of the Switch-on and switch-off bias. The voltage-dependent proportions for both is able to deliver the above-mentioned transverse circle if it has a suitable additional voltage is inserted, which the voltage drops across the ohmic resistances of this Capable of covering the bias circuit, or if its connection from the point ) z1 is placed away to the center tap 1a of the switching inductor winding 22. Will if a relatively extensive partial level control is desired, this can be done by an additional valve in the cross circuit of the pre-magnetizing current in the switch-on direction suppressed and thus a premature magnetic reversal of the choke when switching on prevents «-earth.

Claims (2)

PATENT CLAIMS: i. Mechanical switching converter, the contacts of which are electromagnetically closed and held against a restoring force and are in series with switching chokes for generating on and off current stages, with a special control circuit and with a winding through which the contact current flows (main current winding), characterized in that the main current winding of the magnet system as whose only Steuerwick-Jung is involved in the control circuit. 2. Mechanical switching converter according to claim i, characterized in that the control circuit of the magnet system is combined with a switch-on bias circuit of the associated switching inductor in such a way that the current flow in the magnet winding and in the bias winding is initiated by a common control means. 3. Mechanical switching converter according to claim 2, characterized in that, ß the magnet winding and the switch-on bias winding are in parallel branches of a common control circuit. .4. Mechanical switching converter according to Claim 2, characterized in that the magnet winding and the switch-on bias winding are connected in series in a common control circuit.