DE1255175B - Forward and backward working impulse-controlled multi-stage actuator - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

PATENT LETTERING

Int. Cl .:

. HOIh

German class: 21c -45/03

Number:

File number:

Registration date:

S 93961 VIII d / 21c

October 29, 1964

November 30, 1967 June 6, 1968

Display day:
Issue date:
The patent specification corresponds to the patent specification

The invention relates to a forward and backward working pulse-controlled step actuator for step-by-step switching of linearly graded electrical switching elements, in which the control current paths of the Step switches are prepared using auxiliary contacts from the previous steps.

According to an earlier proposal (patent application S 79836 VIII d / 21 c), a forward and backward working step actuator in both forward and reverse directions remotely operated impulse relay and another relay can be used to change direction. This Relays operate the step switches via two switching lines and two additional holding lines. This Step actuator is suitable for an AC control voltage as the input voltage.

Such a step actuator can be fictional. can be simplified according to the fact that the tap changer are alternately connected to one of two switching lines, depending on which ao speed from the switching position of an input impulse relay to one pole of an input voltage source connected. The contactors are connected to two holding lines by their auxiliary contacts connected that in each case one auxiliary contact is connected to the self-holding contact connected to one and the same holding line for the contactor itself, an auxiliary contact alternates between the following contactor of the switching lines and the third auxiliary contact connects the previous contactor to the other holding line. In the auxiliary contact lines facing away from the contactor windings, there are rectifiers, which are shown in Direction of the step contactors are open. The holding lines are via the switch of a monostable Relay can be connected to the control voltage alternately, and the input current impulse relay and the changeover relay can be controlled via a pulse generator in such a way that they cause step contactors to be switched on Control pulses switching the changeover contact of the input current impulse relay and switching on of the changeover relay cause the impulses that cause the step relays to switch off on the other hand, in addition to switching the input impulse relay, switching off the switching relay cause.

The input current impulse relay switches on with each input pulse via one of the two switching lines Stage, while the changeover relay only receives the required one when changing the switching direction Energizes the holding line. In the event of a power failure, the multiple switches take their starting position back on. The arrangement requires forward and backward working pulse-controlled multi-stage actuator

Patented for:

Siemens Aktiengesellschaft,

Berlin and Munich,

Erlangen, Werner-von-Siemens-Str. 50

Named as inventor:

Oskar Funk, Buchheim near Freiburg

thus no additional elements for a zero return.

For further explanation of the subject matter according to the claims, reference is made to the drawing. In

F i g. 1 shows an arrangement for switching linearly graded capacitors;

Fig. 2 shows the use of such a step actuator to expand another Step actuator with binary graded capacitors.

According to FIG. 1, six capacitor stages K _x to K ₆ with mutually identical capacities are provided, which are to be switched one after the other. It is assumed that the capacitors are not switched directly by the tap changer, but via contactors circuit breakers, of which only the actuating coil is shown in each case. An auxiliary contact 14 to 64 of a tap changer L ₁ to L _{t is} arranged in each of the feed lines of the actuating coils. The step switches L ₁ to L ₆ can be relays or auxiliary contactors, for example. If step switches with sufficient switching capacity are provided, the additional

809 563/71

Union, unspecified switches of the capacitors AT ₁ to K _t are omitted. The step switches L ₁ to L ₆ are each assigned via a normally open contact 11, 21, 31, 41, 51 and 61 to a holding line V for the forward switching and in the same way via auxiliary contacts 23, 33, 43, 53 and 63 of the next step Switches L ₂ to L _{6 are connected} to a hold line R for the reverse switching direction. The .Schalter L ₁ is to a switching line, S ₁ directly and the switches L ₂ to L ₆ are each via an auxiliary contact 12, 22, 32, 42 and 52 of the switch of the previous stage in alternating order to a further switching line S ₂ and the switching line S ₁ connected. The switching lines S ₁ and S ₂ are connected to the positive pole of the DC input voltage CZ ₁ via a changeover contact if of an input relay W. The input relay W is a pulse relay that receives its switching pulses from a pulse generator J, which can be, for example, a reactive power controller operating as a three-point controller, or by hand via a button H for switching up or T for switching down or the forward and reverse switching direction . The holding line F is connected to the positive pole of the input DC voltage source via the raise button H and the line R via the lower button T. The holding lines V and R are also connected to the positive pole of the input DC voltage source via a changeover contact u of a changeover relay U for the change of direction, so that one of the two holding lines always has a positive potential with respect to the negative pole of the input DC voltage source. The changeover relay U is at Impulsgäbe on the hold line V turned on by the charging current of a capacitor C _n and places a switch u positive potential on the hold line V. When changing the shifting direction and the second line end of the coil of the switching relay receives U on the hold line R the reverse switching direction positive potential. The relay U drops out and thus switches the positive potential of the input voltage to the holding line R for the reverse direction. The capacitor C _n discharges through a parallel resistor R _n . In the supply lines of the relays U and W there are decoupling diodes D _U1 and D _B2 or D _m and D _W2 . In the same way, each supply line of the step switches L ₁ to L _{6 contains a decoupling diode D 11} to D ₆₂ polarized in the direction of flow of the control current. A decoupling diode D _v and D _r is also provided in each of the holding lines V and R.

For example, if the reactive power meter of the pulse generator / measures an inductive reactive power, for the compensation of which it _{is necessary to switch on the first three stages JC 1} , K ₂ and K ₃ , the holding line V receives a forward pulse which switches on the input relay W via the decoupling diode D _W1 , which gives positive potential to the switching line S ₁ with its changeover contact w , whereby the switch L ₁ receives a stop command via the diode D ₁₃ and switches the stage K ₁ on. At the same time, the changeover relay U is switched on by the forward pulse, which gives the forward direction via its changeover contact it positive potential to the holding line V i üf. The switch X ₁ thus holds itself via its auxiliary contact 11. The second pulse in the forward direction switches the input field W again; applies the positive input potential to the sound line S ₂ and thus switches on the step switch L ₂ and thus the second step K ₂ via the diode D ₂₂ and the auxiliary contact 12 of the step switch L ₁ . The step switch L ₂ remains on its normally open contact 21 and closes its normally open contact 22 in the input line of the switch L ₃ , which is actuated in the manner described above by the third switching pulse and thus switches on the third step K _{3. The following stages L 4} to L ₆ can also be switched in the same way. With the first impulse

ίο the switching direction is thus always determined and one stage switched at the same time.

If capacitive reactive power occurs, it should be switched back to the second stage K ₂ , for example. The output of the pulse generator J sends a pulse to the hold line R, which applies positive potential to the lower end of the relay coil of the switchover relay U via the decoupling diode Du ₁ and thus causes this relay to drop out. The holding line R receives via the changeover contact u of the relay U

ao positive potential. This eliminates the holding current for the switch L ₃ via its contact 31. At the same time, the input relay W removes the potential from the switching line S ₁ and applies it to the switching line S ₂ . The switch L ₃ drops out and switches

«5 the level K ₃ off. In the same way, stage K ₂ can be switched off by a subsequent pulse in the reverse direction and stage ^ f _{1 can also be} switched off by a further pulse.

In the case of step actuators for switching larger outputs, for example if the output of a step with binary gradation would exceed the switching capacity of normal contactors or viewers, it may be useful to provide a step control element with binary gradation in the preliminary stages and linear gradation in the output stages, such as it in the embodiment of FIG. 2 is shown. The stages Kb ₁ , Kb ₂ and K _Bi are graduated in binary. Their sizes behave like 1: 2: 4. According to an earlier proposal (patent application S 78720 VIII d / 21 c), they can each be switched by a pulse relay S ₁ , B ₂ and B ₄ , which are provided with bistable and monostable contacts. The impulse relay B _{1 of} the first stage is connected _{to the pulse generator via decoupling diodes Db 1} and Db ₂ via the two holding lines V and R , which is shown here in a simple manner as a button H for switching up and T for switching down or down . An AC voltage source R, Mp , to which an input capacitor Ce is connected in parallel, is provided as the input control voltage. The input line contains an input diode De- Furthermore, a decoupling diode D ₁ - and D _{r are} provided in the holding lines between the binary step control element and the linear step control element. The rush relay JJ ₂ and B _{4 of} the stages Kb ₂ and Kß _t are each via a bistable changeover _{contact A 11} and JS ₂₁ and a non-storing working contact B ₁₂ and JJ _{22 of} the rush relay of the previous stage B ₁ or B ₂

fio to the two support rails V and J? connected. In the same way, the input relay W for the linear step actuator is connected to the holding rails V and R _{via a changeover contact B 41} and the non-storing _{normally open contact JJ 42 of} the relay B ₁ . The impulse relays B ₁ to B ₄ and ff change their switching position in each case with an input pulse and retain the switched position even if the input voltage fails. In contrast, for

the step actuators K ₁ to K _{t of} the linear step actuator corresponding to the step actuator according to FIG. i DC relays provided as step switches, which revert to their initial switch position in the event of a power failure. _

To compensate for a reactive power that occurs, for example, all stages of the binary step positioner and stages K ₁ and K _{z of} the linear step positioner should be switched on. With the first pulse by pressing the higher button H , the impulse relay A _{1 of} the first stage ATb _{1 is} switched on via the decoupling diode Db _1. The stage relay B ₁ switches its contact B ₁ ^. The working contacts B ₁₂ as well as B ₂₂ and B ₄₂ are only closed during the duration of the switching pulse of the associated impulse relay, so that they can be disregarded in the following description. With the second pulse, relay B ₁ with its switching contact A ₁₃ switches off stage Kb ₁ , _{switching contact A 11} is switched back to the forward line V and a current impulse is sent to relay B ₂ , which switches its switching contact B _n to the reverse rail R. switches over and with its contact A ₂₃ the stage Kb ₂ turns on. At the third pulse the contact A _{11 is switched} to the reverse line R and the stage K _{1 is} switched on with the switch A ₁₃ , so that after the third pulse the stages Kb ₁ and Kb _{2 are} switched on. With the fourth pulse, relay B ₁ switches off stage ATs ₁ . The relay B ₂ receives a pulse via the changeover contact A ₁₁ and switches its changeover contact B ₁₁ to the forward switching line V and the stage Kb ₂ off via the switch B _23. Relay B ₁ receives a current impulse via contact A ₂₁ , which switches on stage KBi with its contact B _43. The fifth pulse switches on stage Kb _{1 via relay A 1} . With the sixth pulse, the level Kb ₁ ■ is switched off and Kb ₂ switched on, corresponding to the second pulse, so that after the sixth pulse, the levels Kb ₂ and A ^- B _{4 are} switched on. With the seventh pulse, stage B ₁ is also switched on. The eighth pulse switches the relays B ₁ , B ₂ and B ₄ in the same way and thus the stages A "bi, Kb ₂ and A" b ₄ off and the relay W via the changeover contact B _n , which with its changeover contact the Switching line S ₁ is energized and thus the stage K _{1 is switched} on via the relay L ₁ . Then the stages / Ta ₁ , Kb ₂ and ATb _{4 are switched on} again in a corresponding manner and then these stages are switched off again by the subsequent pulse and stage L ₂ is switched on via the relay W. The stages A ^ b ₁ to Kb ^ are switched on again by further impulses. With three binary graduated upstream elements, every eighth switching impulse is passed on to the linear stepped control unit.

For example, if you want to switch back to levels Kb ₁ and Kb ₂ , the push button T sends an impulse to the reverse line R , which switches off level Kb ₁ via the impulse relay B ₁ and switches the switching relay U via the diode D _U1 and thus positive voltage on the reverse rail R. Since the changeover contact maintains its position, stage L _{2 is} only switched off when stages B ₁ , B ₂ and 5 _{4 are} switched off and the input relay W is then switched. With the second reverse pulse, stage Kb _{1 is} switched on and stage ATb _{2 is} switched off. Thus, after the second pulse, ATb ₁ and ATb _{4 are} switched on. With the third pulse, contact B _{11 is switched} to the forward line V and stage B _{1 is} switched off via switch A _13. With the fourth pulse, the stage ATb _{1 is} switched _{on via switch B 13;} the contact D _{11 is} switched to the reverse line, a current impulse is given to the relay B ₂ , which switches the contact B ₂₁ to the reverse line, the relay B ₇ , issued a current impulse and thus the stage Kb ₂ switched on. The relay B ₄ switches its contact B ₄₁ to the line V and switches off the stage ATb ₄ via its contact B ₄₃ , so that the capacitor stages ATb ₁ and ATb ₂ are switched on after the fourth pulse. In a corresponding manner, the stages Kb _x and ATb _{2 are} switched off, and then the stage K _{3 is} switched off and the stages ATb ₁ , ATb ₂ and ATb _{4 switched on} again by the following pulse via the relay W. In the prescribed manner, these stages ATbi, ATb ₂ and ATb _{4 are} switched off again by the following pulses and stage AT _{1 is switched} off and stages A "b _1; Kb ₂ and ATb _{4 are switched on} again by the following pulse _{switched back to stages ATb 1} and Kb ₂ - According to the exemplary embodiment, the stage actuator is intended to switch capacitors, but it can also be used to switch other electrical stage members, for example resistors.

Patent protection is only sought for the entirety of the features of each claim, that is including a back relationship.

Claims (3)

Patent claims: 1. Forward and backward working pulse-controlled step actuator for stepwise switching of linearly graduated switching elements, in which the control current paths of the step switches are prepared by auxiliary contacts of the previous steps, characterized in that the step contactors (L ₁ to L ₆ ) each alternately to one of two switching lines (S ₁ , S ₂ ) are connected, one of which is connected to a pole of an input voltage _{source (CZ 1} ) depending on the switching position of an input current impulse relay (W) , and that the step contactors (L ₁ to L ₈ ) through their auxiliary contacts are connected to two holding lines (V and R) in such a way that an auxiliary contact (21, 31 ...) forms the self-holding contact for the contactor itself connected to one and the same holding line (V) , an auxiliary contact (12, 22, 32 ...) the following contactor (L ₂ , L ₃ ...) alternately connects to one of the switching lines (S ₁ , S ₂ ) and the third auxiliary contact (23, 3 3, 43 ...) the previous contactor (L ₁ , L ₂ , L ₃ ...) connects to the other holding line (R) so that the auxiliary contacts (11, 21 ... 52 ) Rectifiers (D ₁₁ ... D ₆₂ ), which are open in the direction of the step contactors (L ₁ ... L ₆ ), that the holding lines (V, R ) alternately to the control voltage (U) can be laid and that the input current surge relay (W) and the change-over relay (U) in such a way via a pulse (/, H, T) can be controlled, that the switching in of stages contactors (L ₁ ... L ₆₎ effecting control pulses the switching of the changeover contact of the input impulse relay ( W) and the switching on of the switching relay (U), the switching off of the step relays (L ₁ ... L ₆ ) on the other hand In addition to switching the input impulse relay (W), it also switches off the switching relay (U) . 2. Step actuator according to claim 1, characterized in that the charging current of a capacitor (C _a ) is provided for switching on the changeover relay (U). 3. Step actuator according to claim 1, characterized in that the input current impulse relay (W) of the output stage (.B ₄ ) of a binary step positioner is arranged downstream. Considered publications:
German patent publication No. 889 029. 1 sheet of drawings 709690/377 11.67 © Bundesdruckerei Berlin