DE1474338A1 - Switching with reed switches - Google Patents

Description

Applicant: General Electric Company, Schenectady, New York, N.Y. United States

Switching with reed switches

The invention relates to circuits made up of changeover switches, in particular shift registers and counting devices, use the circuits with magnetic reed switches.

So far, electromechanical relay devices have been used as basic switching elements for circuits such as shift registers. The circuits made up of common relays gave sufficient results, but left room for much improvement. It is a disadvantage of electromechanical relays in a memory circuit that they have to be supplied with constant energy ν, otherwise the signal stored in the relay is lost. Therefore, a network failure means the loss of all stored signals. Since the operation of a relay generally depends on rather tight current tolerances, known circuits have the disadvantage that changes in the power supply can significantly influence the circuit function without a complete failure of the circuit. Another disadvantage of circuits with electromechanical relays is that the loss of a stored signal depends on the setting of the switching process. This requestiKg.-dQ-jP. exact setting means one

more extensive circuit and less reliability on the

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Circuit. Circuits made up of electromechanical relays are extensive because of the additional elements that are necessary to ensure the memory function. A reed switch, on the other hand, which can permanently store, allows the avoidance of additional elements and the assembly a complete circuit made up of a few basic units.

Known circuits that are either electromechanical ^ relays or magnetic reed switches have the disadvantage that the switch contacts that interrupt the current and conduct, have a short lifespan. In order to remedy this disadvantage, the current in the circuits according to the invention not by the reed switch in the basic circuits interrupted. The avoidance of power conduction and interruption by the reed switch in the basic circuits allowed also the resolution of another scientific problem, switch bouncing. Another problem with known circuits of this type is the mutual interference of the control coils by inductive Coupling. These difficulties and disadvantages of the known circuits are exploited according to the invention advantageous properties of the magnetic tongue switch overcome in special circuits.

It is therefore an object of the invention to provide new and improved circuits based on the. magnetic reed switches which are fast, with a high degree of efficiency and ν can be issued functional with a significantly increased service life of the switching elements. Furthermore, circuits are to be specified in which the permanent storage is achieved regardless of a power failure is used without using different types of switching elements

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will. Furthermore, circuits are to be described that perform all the desired functions without interference from inductive coupling between successive units.

The circuit according to the invention uses two sets of identical magnetic tongue retainer (hereinafter referred to as Called switch). Each switch has a movable contact element and a pair of stationary contacts. The movable one Contact element is always in contact with one of these stationary contacts. A pair of magnetic coils or a control device belongs to every switch and controls the position of the movable contact element. Sachdem the movable contact element has been moved by force from one of the coils to a stationary contact »an auxiliary permanent magnet holds that movable Kontakteleinent in this position until it is due to the action of force is moved to the other stationary contact.

According to the invention, an electrical circuit is provided with a first set of magnetic reed switches and a second Set of ZuniTenu switches; with a switch in the first sentence the changeover switch (hereinafter referred to as the first switch) and a switch in the second set of changeover switches (hereinafter the second Called switch), whereby each of the switches has a flexible tongue, which "can assume both contact positions; with a first and a second magnetic control coil for each switch, the power being supplied to the first magnetic control coil causes the tongue by force in a first of the • Contact layers is moved »and taking the energy supply to the second magnetic control coil causes the tongue to be moved into a second contact position "; with a magnetic auxiliary steep for the determination of each tongue in the respective contact position, to

* r 003886/1652.

it is moved into the other position by the action of force, with an electrical device for the selective supply of energy to the magnetic control device of a first switch and a magnetic control coil of a second switch characterized by an electrical circuit that sets the the switch connects so that power is supplied to a special magnetic control coil of a first switch is determined by the position of the tongue of a second switch, and the energy supply to a special magnetic control coil of a second switch is determined by the position of the tongue of a first switch.

The invention will be explained in more detail with reference to the drawing. Show it:

1 shows a schematic basic circuit of a shift register;

Pig. 2 shows a schematic basic circuit of the shift register by Pig. 1, which can slide both forward and backward shows;

3 shows a schematic circuit of a simultaneous shift register;

4 shows a schematic circuit of a sequence shift register;

5 shows a schematic circuit of a ring counter;

6 is a schematic circuit diagram of a flip-flop circuit made up of reed switches; 7 shows a schematic circuit of a binary counter; and

Fig. 8 is a schematic circuit diagram of an addition and subtraction counting register.

In Fig. 1, the basic circuit of a scan register is shown.

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made using switch. The shift register has a first set of switches, indicated by the letter A. and a second set of switches that are identified by the letter B. Each switch A has a movable contact element 1, stationary contacts 3 and 5 and a control device 7 and 9. The contact element 1 is always either in a first contact position when it is stationary Contact 3 touches, or in a second contact position when it touches contact 5. When the movable contact element the Touches contact 5, it is moved to contact 3 by the action of force when energy is supplied to the first coil 7. Similarly, if the contact element 1 in contact with the stationary contact 3 is located, the supply of energy to the second coil 9j causes the contact element 1 by the action of force to the contact element 5 is moved. No matter which of the stationary contacts is touched by the movable contact element 1, a (not shown) Auxiliary device holds the element 1 in the respective position until it is through the action of force by the control device 7 or 9 is brought into a different position.

The switches B are identical to the switches A and they have a movable contact element 11, stationary contacts 13 and 15 »and control coils 17 and 19 · The first coil 17 pulls the contact element 11 by force to the stationary contact 13 and the second coil 19 the element 11 to the contact 15. As with switches A, an auxiliary device (not shown) stops the element 11 in the respective contact position in which it was last brought by the control devices 17 and 19.

The power supply of the Sohalt is by means of a DC voltage source gwisahen the lines 2t and 23 made ..

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From Fig. 1 it can be seen that the movable contact elements'. 1 the switch A and the movable contact elements 11 of the switch B are connected to the line 21. The line 23 is connected to the movable contact element 25 of a slide switch 27. The slide switch 27 also has stationary contacts 29 and 31. The stationary contact 29 is connected to the line 33 and the stationary contact 31 is connected to the line 35. One end of the first control coil 7 of the switch A is connected to one end of the second control coil 9, and this common end is then connected to the line 35. T is similar

one end of the first control coil 17 with one end of the

, second control coil 19 of switch B and this common end ί connected to line 33.

During operation, an input signal reaches either the first control coil 7 or the second control coil 9 of the switch A of the first stage. This input has the same polarity as that of line 21 so that when the movable EIE J ment ₁ 25 of the switch 27 to the stationary contact 31 connected ^t, what is known as a shift position of a control coil of the formwork Ί ters A power is fed. The supply of energy to a control coil of switch A brings element 1 into contact either

* with contact 3 or contact 5. The movement of the contact element 25 of switch 27 to contact 29 »known as the insert position, causes one of the control coils 17 or 19 of the switch B in the first stage with energy from line 21 via the element 1 is fed to line 33 and then to line 23. This ensures that the input signal is stored in switch B. will. In this circuit, the switches A act as input brackets and the switches B as memory units, and "ietsitertf'Wte'uern the input switch of the next stage.

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Long signal after another shift has occurred. Therefore causes the movement of the contact element 25 of the switch 27 between the contacts 29 and 31 a selective energy supply to a control coil of switch A and to a control coil in set B. In addition, "means the connection of the contact 3 with the coil 17, the contact 5 with the coil 19 »of the contact 13 with the coil 7, the contact 15 with the coil 9 that the energy supply to a special control coil is controlled by a switch from the other switch set. The optional energy supply of lines 33 and 35 in this way causes a signal from switch A to switch B and back transferred to a switch A of the next following stage will. This function shifts the information from stage to stage until it has been removed from the exit.

While the shift register is in operation, it is also possible to supply energy to an output consumer 37. This Load 37 is connected in parallel to a control device of a switch. With this circuit, the current is fed to the Consumers interrupted during each actuation of the switch 27, since it is connected to the line 33, but the consumer current is not interrupted by the reed switch in the register, so that the contact life is increased.

It is sometimes desirable to have an indication of the power supply to a particular unit in the register. That can through the use of threshold devices 39, for Example Feon lamps. To achieve this ad becomes an AC voltage source via the transformer 41 connected. The secondary winding 43 of the transformer 41 has

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one end connected to the line 33 and the other end connected to one of the desired devices 39. That the other end of the devices 39 is connected to a stationary contact in the shift register such as the stationary contact 5 of the Switch A, connected. When the contact element 1 is on the contact 5, and the switch 27, the contact element 25 on Contact 29 is, the full DC voltage is applied to the devices 39. However, this voltage is less than the ignition voltage of the devices 39> so that the devices 39 only fire when the half-waves of the one coming from the transformer 41 AC voltage are added to the DC voltage in order to exceed their ignition voltage.

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Pig. 2 shows the same basic circuit as Pig. 1 except that these circuits can be used for reverse and forward shifting. This additional puncture has the installation of the control coils 45 and 47 », which correspond to the control coils 9 and 7, in the switches A to the pole. While one end of the control coil 9 is connected to the contact 15 of the switch B of the previous stage, one end of the coil 45 is connected to the contact 15 of the switch B of the next stage. Of course, if a reverse shift is done, this would actually be the previous stage for the signal to be shifted back. To ensure the backward shift, an additional slide switch 49 is provided in the circuit. A slide switch 27 ', which is similar to the switch 27 in the basic circuit, has a movable contact element 25 ^f which connects to each of the stationary contacts 29' or. 31 'can be brought, which are connected to the lines 33' and 35 '. The element 25 ′ of the switch 27 ′ is connected to the stationary contact 51 of the slide switch 49. During the "forward shift", the movable contact element 53 of the slide switch 49 is on the stationary contact 51 "in order to represent the circuit which has been described in connection with the slide switch 27. During the backward shift, the contact element 25" of the switch 27 "is at the Contact 31 'to the normal power supply to the control coil to allow' 17 and 19, the switch B. the slide switch 49 still has an additional stationary contact 55 which is connected to the auxiliary line 57. the conduit 57 is connected to th e common Ends of the control device 45 and 47 ip- in the same way as the line 33 'is connected to the common loads of the control device 7 and 9. They

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Shifting backwards is then the same as shifting forwards .

In Pig. 3 shows how the basic circuit is applied in a .... Simultaneous shift register control circuit. the ■ Basic circuit is the same as that of Fig. 1, see above that it need not be repeated here. An additional information processing channel is available, there but every channel is identical in operation, it is sufficient to discuss one channel. A change in the circuit that came in handy does not change the circuit function, is done by moving the slide switch 27 '' to the other side of the Circuit has been laid. Therefore the sliding and additional lines are 35 "and 33" each with the movable contact elements of the switch and not with the common ends of the Control coils connected. In addition, the movable contact element 25 ″ of the slide switch 27 ″ is connected to a common Supply line 59 connected. The negative pole of the agitation part, line 61, is connected to the common ends of the control coils during operation, and the positive pole of the power supply, line 63, is only connected during erasing, which will be described later.

The simultaneous shift register is provided with an input control relay 65 which has a pair of control coils 67 and 69> a movable contact element 71 and stationary contacts 73 and 75 . The relay 65 is controlled by an input reset switch 77 and an input trip switch 79. During operation, the actuation of the switch 77 _{f has the} effect that the control pulse 67 dea relay 65 energy is supplied and therefore the contact element 71 comes into contact with the stationary contact 73.

f ■ F - ■ r ■ "'■"'''" ¹ ^ '

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In this position of the contact element 71, an input signal can be entered via the input switch 85. If the input, tswitch 85 is actuated, the control coil 9 of the switch Λ of the first stage via the diode 83, the contact element 71 » the stationary contact 73 and the input switch 85 are energized. If it is desired to cancel this signal, before it is transmitted to the rest of the system, this can be achieved by actuating the input release switch 87. Vienji it is desired that the information reaches the rest of the system, the switch 79 is operated, so that the ^ control coil Energy is supplied and thereby the contact 71 comes into contact. In this way, the energy supply to the control coil 17 or 19 of the switch B of the first stage via the diode 81 is reached. When the control coil 19 is energized, so that the element comes to contact 15, causes the next shift, the movement of contact 25 'to contact 31' 'that the control coil 7 of the Switch A of the first stage is supplied with energy via the diode 91 and prepared for the input of a further signal is. It can be seen that switches B have an additional movable contact 93 and stationary contacts 95 and 97 in each Have level. These contacts can be like in the second stage of J? Ig. 3 can be switched to a coded withdrawal signal to create.

In some cases it is desirable to completely remove all of the signals that are present in the simultaneous shift register delete to enter an entirely new set of information. The deletion of the signal present in the simultaneous shift register is made by the cancel switch 91. The common

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Ends of the control coils of all switches are usually connected to line 61 via lines 101 and 103. It can be seen, however, that the control coil 9 of the switch A is connected to the line 103 and not to the line 101 after the first stage. The actuation of the system cancel switch ensures that only the line 35 ¹ 'is supplied with energy via the diode 105, and that the line 103 is connected to the positive line 63 and not to the negative line 61. Therefore, if the switches B are arranged to energize the control coil 7 of the switches A, they will continue to be energized while the system is being cleared. If, however, the switches B are in such a state that the control device 9 of the associated switch A is supplied with power, actuation of the system clear switch causes a reverse current flow to the magnetic control device 9, so that the contact 1 goes to the contact 3 and not to the contact 5 is moved. This means that then all "movable contacts 1 are at the stationary contact 3, so that after the system extinguishing alarm has returned to its normal position, the" contacts 11 "allier switch B by switching the element 25" of the slide switch 27 ' are brought to the contacts 13 and the system erasure is completed the presence of the diode 190 is required to prevent interference from inductive Xop development.

Another type of scan register is shown in FIG. With this type of register, the information is "stacked" in the steps backwards to the exit. This circuit prevents

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entering new information in a stage until any previous information has been removed from this stage. the Transfer of information from one level to the next Stage can be due to the fact that the next one follows- * de stage has not received any information, or it can occur because the information in the next following stage as a result of the decrease in information at the output of the system has reached a further subsequent stage. This type of shift register is called a sequence or memory shift register. The main difference between the sequence shift register and the simultaneous shift register is that the sequence shift register an additional channel is required, which is used as a control channel; ^ is known. The circuits of both the control and information processing channel (or channels) are essentially those of 3? ig. 3. It should be noted that resistors 6 and 8 are present in the circuit. These resistors are built in to destroy the energy at the coils 7 and 9, respectively no energy is supplied to them. There are also some small changes, for example the slide switch 27 '' is through a ', / echselstromschaltanordnun ^ 111 has been replaced. The alternating current The circuit 111 includes a transformer 113 and diodes 115, 117 and 119. Therefore, the switching is done with the half-waves made of alternating current, and an independent switching control is not necessary. As a result of the higher holding speed with a 60 Hz signal, the independent input reset switch is used in the simultaneous shift register circuit of Fig. 3 has also been omitted.

It's out of #ig. 4 it can be seen that an additional movable

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lichds contact element 121 and stationary contacts 125 and 125 closed. the switches B in the control channel have been added. These switching elements are not the same as the withdrawal . contacts 93, 95 and 97 of Pig. 3. The common ends of the '"." Control coil 7 and the control coil 9 of the switch A in one stage are connected to the movable contact element 121 of the switch B in the same stage. All stationary contacts are connected to line 127, which is the supply line for the switch A control coil. The stationary contacts 125 are connected to the contact 121 of the switches B in the following} stage. The contact 121 is connected to the common ends of the control coil 7 and 9 of the switches A in both channels.

In operation, each input signal applied to the information processing channel causes energy to be applied to the control coil 9 of switch A in the first stage of the control channel. If the signal is passed on in the control channel, it can only to get to the switches A when the contact 121 of the switch

B is at stationary contact 123 for this stage, or if contact 121 of a subsequent stage is at stationary contact 123. When the information reaches the last stage, contact 121 is on stationary contact 125 of that stage. Therefore, no subsequent information can be stored in the last stage, because it is not possible to supply 7 and 9 this stage energy d $ n control coils. The next following information bit is therefore stored in the next preceding stage, which can then not receive any further information. This goes on in reverse until all stages have been provided with information, or until the information in the last stage has been removed

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is, in the latter 3? a.-l then the information in each preceding one Step passed through the canal.

It was mentioned above that the additional contacts of switches B in the control channel are not the same as the release contacts in the simultaneous shift register. In the information-processing channel, however, there are discharge contacts 93 ', 95' and 97 'which correspond to those in the simultaneous shift register. A branch point is shown in connection with the Ausspeicherkontalcten 93 ', 95' and 97 '. This branch point has a control relay 129 which is approximately the same as the input control relay. At this branching point, the series connection of the additional contacts for the switch B is interrupted. If the series connection is interrupted, the input signals of a control channel of this stage are prevented from continuing to the next following stage. The control relay 129 has a movable contact element 131 and stationary contacts 133 and 135. When the limit switch 137 for the control relay 129 is actuated, the contact element 131 goes to contact 135 and the information in switch B in the stage is transmitted to the next following stage, if the withdrawal signal at 93 'and 97' is not the normal gesciJ-Ossenei- contacts connected to lines 139 and 141 opens. However, if the withdrawal signal opens the normally closed contacts, the information is not passed on to the next stage, but is diverted to the withdrawal device. When the signal is transmitted to the next succeeding stage, the return of contact 131 to contact 133 allows the signal to be transmitted through the channel.

Kin release limit switch 143 at the output is in the last

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Level available. The switch 143 is the only control device the control coil 7 of the switch A. When the switch 143 is operated, the contact 121 becomes the additional Contacts of switch B in the last stage brought to stationary contact 123 to allow the input of another signal in the last stage to allow ^. That enables the one at the entrance of the 'information processing channel' information "piled up" advances to the exit.

A ring counter is shown in FIG. The ring counter is essentially in the same way as the basic circuit of Pig's shift register. 1 switched. The main difference is the incorporation of the reset switch 129, which is a movable Contact element 130 and stationary contacts 133 and 135. During normal operation the meter touches the movable Contact element 131 the stationary contact 133. During operation of the ring counter, however, it is often necessary to switch the circuit back so that a new counting sequence can be started can. This function is achieved by switch 129 by that when the contact 131 is switched to the contact 135, the Circuit is switched back or deleted. The only difference between this operation and complete deletion is that contact 1 of switch A in the first stage is on contact 5 and not on contact 3. This ensures that an input signal generates a new sequence of counting pulses. The remaining contacts 1 are on the Contacts 3 or in normal extinguishing position. The downshift is done by drawing current through the diodes 137 from the stationary Contact 135 of switch 129 flows. The line connected to contact 135 can usually be switched back busbar.

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be called. The diodes 137 are provided with a special control device the switch B connected.

In order to achieve the function of the ring counter, it is necessary to switch the stationary contacts 13 and 15 of the switch B in the last stage with the control device 7 or 9 of the switch Connect A in the first stage. This closed loop circuit ensures successful operation of the ring counter. During the operation of the ring counter it is in generally desirable to have an indication of the presence of a particular signal at each stage. With the present Circuit, output signals are picked up at the outputs 139, which are transmitted to the stationary contact of switch A in each stage. This is how the ring counter works Completely.

Pig. 6 shows another embodiment of a circuit, the reed switch used. The puncture of this circuit is similar to that of a normal plip-plop circuit, and therefore it is a flip-plop control unit has been called. In the fundamental, single-stage flip-flop control unit is a switch A. and a switch B is available. Every contact and every control device of these switches are the same as with the shift register by Pig. 1 referred to. The stationary contact of the switch A is connected to the control coil 17 of the switch B. Similar the stationary contact 5 is connected to the control coil 19. The connections of the stationary contacts of switch B are of those used in the basic circuit of the shift register Connections have been accepted. The power supply to the circuit is performed by a DC power supply that supplies the energy via lines 141 and 143. A selected one

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Control coil of switch A and a selected control coil of switch B are optionally supplied with energy, wherein the optional energy supply is controlled by the pulse switch 145. The pulse switch 145 has a movable control

clock element 147 and stationary contacts 149 and 151. If that

11

Movable contact element T of switch B is at stationary contact 15, control coil 7 of switch A is energized and it causes element 1 to come to contact 3. When the contact 147 is then moved to the stationary contact 151, the control coil 17 of the switch B is energized and the movable contact 11 thereby comes to the stationary contact 13. The return of the contact 147 to the stationary contact 149 then causes the energization to the control coil 9 of switch A. In this way, contact 1 comes to contact 5. A further movement of contact 147 to contact 141 supplies the control coil 19 of switch B with energy and switches this switch back to its original position. Another consequence of the process just discussed can then take place. The energization of the control coil 19 also allows an output signal to be taken from the output 153. This output signal can be used to create a circuit using a series of these units. The output signal is generated after every other input pulse, so that a flip-flop-like operation is achieved. For a series connection of these units, a signal from 155 is picked up and passed on to the movable contact element 11 of a switch B in the next following stage.

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In Fig. 7 there is shown a circuit comprising a series of Units of Fig. 6 are used. In this figure, the individual units are connected in such a way that they form a binary counter. The binary counter circuit is achieved by taking an output pulse from output 153 and to contact 1 of switch A. the next stage is passed. Likewise, the pulse for contact 11 of switch B in the second stage is from the output 155 removed. This means that an impulse is only passed to the moving contacts of the switch in the second stage becomes when two impulses have come to the corresponding moving contacts of the first stage. Each of the following is similar Stage connected to the movable contact of switch A of the following stage, which is connected to the output 153 and the contact 11 of switch B in the output 155 of the previous stage first connected to the following stage. Therefore, a pulse comes to the contact T of the switch A in the third stage after two impulses have come to contact 1 of switch A in the second stage. But since two input pulses get to the first stage before a pulse is received in the second stage, a total of four first input pulses must come to the first stage, before a pulse occurs in the third stage. Hence the number of original input pulses required for one pulse needed in a stage twice as large as the number of original input impulses used to generate a Pulse in the previous stage. In this way, a binary counter is formed, with the output of each stage corresponds to a digit in a number system based on the number 2.

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Pig. 8 shows an addition and subtraction counting register. This counting register is based on the basic circuit of the shift register by Pig. 1 and not on the flip-flop unit of Fig. 6, but it is connected to do the simple math Can perform operations of addition and subtraction. These operations are achieved by a circuit which has the properties of both forward and backward displacement, as the circuit of FIG. 2. Instead of using additional control coils such as 45 and 47 in FIG however, this embodiment is based on the additional installation of a movable contact element 57 and stationary contacts 159 and 161 in connection with the switch B. In this circuit, the stationary contact 159 is with the control device 7 a switch A in the previous stage and the stationary one Contact 151 connected to the control device of the same switch.

In addition, the function of the circuit is the same as that of Fig. 1. In subtraction, a subtraction signal is produced given to the circuit which essentially cancels the signal in the last stage of the unit. In the presence of additional Subtraction pulses reverse this cancellation to cancel the signal in each preceding stage. Hence are Addition and subtraction possible.

In the description of the various exemplary embodiments according to the invention, general terms are used for description the reed switch has been used. The term "movable contact element" has been used to describe the movable contact element Describe contact of the reed switch. This movable contact element can specifically be a flexible tongue. Similar

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the general term "control device" has been used quite often to refer to the device which is responsible for the Control of the location of the flexible tongue is used. This control device is generally an electromagnetic one Be coil, after it is not limited to such a definition. Also, the term "auxiliary device" has been used to refer to the arrangement for the detection of the deflectable tongue able to designate in which she was last brought. In practice, the auxiliary device becomes a permanent magnet arrangement but the former can also be different.

Claims

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Claims (9)

Claims > '* "* ■ · ———« ——— ^ —— - 1 · "Electrical circuit with a first set of reed switches and a second set of tongue retainers; with a Switch in the first sentence of the toggle switch (in the following first Called switch) and a switch in the second set of changeover switches (hereinafter called the second switch), each of the switches having a flexible tongue ", § ± e can assume both contact positionsj with a first and a second magnetic control coil for each switch, the Energy supply to the first magnetic control coil "causes the tongue to be moved into a first contact position by the action of force, and wherein the energy supply to the second magnetic control coil causes the tongue to be moved into a second contact position; with a magnetic auxiliary part for the determination of each tongue in the respective contact position until it is moved into the other position by force, with an electrical device for the optional power supply to a magnetic control device of the first switch and a magnetic control coil of the second switch, geke η η is characterized by an electrical circuit (Fig.1) which connects the sets (A; B) of the switches so that the energy supply to a special magnetic control coil (7 »9) is a first switch (A) through the position of the tongue (11) of a second switch (B) is determined, and the energy supply to a special magnetic control coil (17 ₁ 19) of a second switch ■ 009886/1653 - 25 - H74338 (B) through, the position of the tongue (1) of a first switch (A) "is determined. 2. The circuit of claim 1, comprising a shift register, with a first set of switches and a second set of switches »with several information shift stages connected in series, so that each stage has a first switch and a second switch, thereby characterized in that each switch (A; B) has a movable contact element (1; 11) and a pair of stationary Contacts (3,5j 13,15), wherein the movable contact element a first of the stationary contacts in a first contact layer and the other of the stationary contacts can touch in a second contact layer that an electrical circuit has a stationary contact (3,5) of a first Switch (A) connects to a control coil (17, 19) of a second switch (B) in the same stage, and that another electrical circuit a stationary KontaKt a second switch with a control coil of a first switch in the next following stage connects so that the energy supply to a special control coil of a second switch through the location of the contact element of the first switch in the same Stage and the energy supply to a special control coil of a first switch through the contact element of the second Switch is determined in the previous stage. 3. Circuit according to claim 2, with a DC voltage source for the energy supply of the control coils and a first slide switch, which can assume two contact layers to enable the optional energy supply, thereby g e - • 009886/1652 indicates that the shift register (Fig. 2) has an additional first (45) and second (47) control coil for the first switch (A), so that the additional control coil with the stationary contacts (11,13) of the second switch (B ) is connected in a following stage that a second slide switch (49) for the optional power supply to one of the additional control coils of the first switch (A) and a control coil of the second switch (B) is present, so that the actuation of the first slide switch (27 ¹ ) the forward shift of the information in the shift register and the actuation of the second switch (49) causes the information in the shift register to be shifted backward. 4. A circuit according to claim 1 * to 3, wherein the control coils each second switch are connected to the other in a common connection and the shift register further an AC voltage source one end of which is connected to the common connection of the control coils of the second switch, characterized in that each stage of the shift register has a discharge device (39) for Has display between the other end of the AC voltage source (41) and a stationary contact (5) of a first switch (A) is switched so that the position of the movable contact element (i) of the first switch (A) on the extended stationary contact triggers the discharge in the discharge device and generates a display signal. 5. Circuit according to claim 4, characterized in that that the power supply of a second control coil enables the information to the first switch the first stage arrives, and that the energy supply of a 009886/1652 first control coil allows the information to pass to the second First stage switch arrives. 6. A circuit according to claim 4 or 5, characterized geke nn is characterized in that a first end of each drive coil (7,9; 17,19) with a stationary contact (13,15; 3,5) of a switch (B; A) from is a "neighboring S _a tz of switches, in that the other end of each drive coil (17,19) of the second switch (B) and the other end of the first control coil (7) of the first switch (a) with a first line (101 ) that the other end of the second control coil (9) of the first switch is connected to a second line (103), that the first and second lines are connected to one another and to a voltage source (61), that a system extinguishing switch (99 ) is present, which has an erase position and a non-erase position, so that when it is in the erase position, the first line £ uag ( 101 ) separates from the second line (103) and the second line with a voltage source ( 63) with opposite polarity to the voltage source connected to the first line nd that the extinguishing switch, when it is in the extinguishing position, also switches off the device (59,27) for the optional energy supply and a device (59,105) for the constant energy supply with the movable contact element (11) of every second switch (B) and connects a circuit that can bring the system erase switch to its strike and switch it back to its non-erase position, whereby all subsequent levels of the register are cleared. 7. A circuit according to claim 6, with a circuit for the optional Power supply of a control coil of each first switch and 009886/1652 ' - 26 - U7A338 a control coil of every second switch, g e k e η η - characterized by 'an electrical circuit that connects the sets of switches (A; B) in such a way, that the energy supply of a special control coil (17,19). "of a second switch (B) through the position of the contact element "(1) of the first switch (A) is determined in the same stage and the energy supply of a special control coil (7, 9) a first switch (A) determined by the contact element (11) of the second switch (3) in the previous stage is. 8. Circuit according to claim 6, marked ze'ichnet by an electrical circuit (Fig. 6), which the first stationary contact of the first switch with the first control coil of the second switch and the second stationary contact connects to the second control coil, and by means of the first stationary contact of the second switch connects to the second control coil of the first switch and the second stationary contact to the first control coil, the connections from the stationary contacts of the second switch to the control means of the first switch are crossed, so that the movable contact element of the first switch is always in the other contact position by energy supplier a control device of the first switch is moved * 9. Circuit according to claim 8 characterized by several units (Pig * 7) with an output pulse which is derived from the unit when the movable contact element (t) des.ersten switch (A) iat in one of the predetermined contact positions an electrical circuit, the output (153) of each unit with the movable contact element 009886/1651 of the first switch in the following unit connects, by a further electrical circuit (155) which has one predetermined stationary contact of the second switch in. · Each unit with the movable contact element (11) of the second switch in the following unit ν binds, so that a Output pulse in the first unit after every two input pulses arises, so that an output pulse in the second unit after every four input pulses there is an output pulse is obtained in the third unit after every eight input pulses, and that the following units one pulse after generate a number of input pulses twice as large as is the number of input pulses that make an output pulse generated in the next previous stage. 009886/1652 Blank page