DE1513881C - Connection of an open control circuit for digital control of the running characteristics of a synchronous induction motor - Google Patents

Description

2. From a stepper motor controller (British patent specification 960 079) that operates at the start of the acceleration period the first control pulse is extended in time in order to give the motor the required acceleration, with various Speed settings of the motor by setting the pulse period duration the clock generator can be achieved by means of the toggle frequency.

IO

3. From a switching arrangement (Austrian patent specification 224 761) in which the one Pulse generator via a stop interlocking device for a sequence of excitation the circuit that determines the individual stator windings of the electric motor Pulses are blocked or released with the corresponding signal, whereby the driver amplified pulses are fed to a pulse counter in addition to the stator windings connected to a brake circuit responsible for stopping or decelerating is.

The invention solves the problem posed by the fact that one for starting or running the induction motor responsible logic circuit one with the one connected to the binary pulse counter Output of a gate circuit connected inverter circuit, the output of which the input an AND circuit, the second input of which with the lowest counting level of the pulse counter and the last input of which is connected to the OUT output of an interlock circuit, the IN output of which is connected to another AND circuit, the other input of which is connected to the said Output of the gate circuit is connected that the IN input of the latch circuit to a low counting level and the OFF input of the interlocking circuit to the clearing line of the pulse counter is connected and that the outputs of the two AND circuits with an OR circuit are connected, the output of which is connected to the sequence of energization of the stator windings of the induction motor determining circuit is connected, the pulse counter is switched so that from the second counting level before the next higher counting level is applied a pulse each time the lowest count level applied and that for stopping or decelerating the induction motor responsible logic circuit from one of the size of the speed or the moment of inertia corresponding number of the highest counting level of the pulse counter connected downstream, parallel to each other Pulse delay devices are made, each of which is a different one Pulse delay and adjustable, if necessary, different pulse lengths generated and that these delay devices connected in parallel are the inputs of the for the sequence of excitation OR circuit upstream of the stator windings responsible for the logic circuit form. The circuit according to the invention enables the maintenance of precise translational movements and Rotational movements of the elements to be moved, without that after reaching the synchronous speed! If any synchronous oscillation occurs, after the shutdown a vibration can be detected ■ and vibration is generated when an intermittent movement is performed. Also has the invention has a relatively simple circuit structure, so that the functional reliability is high. Furthermore, the invention enables the motor to be operated at a synchronous speed that over its overload frequency lies by the time period between the first two output pulses of the OR circuit is set so that the repetition frequency in between is below the overload frequency located.

Further features of the invention can be found in the claims.

Details of the invention are given below with reference to exemplary embodiments illustrated in figures described. It shows

F i g. 1 is a block diagram for the start-stop control of an induction motor,

Fig. La details in the block diagram according to FIG. 1 used start-stop gate circuit, F i g. 2 a a schematic of a stepper motor,

F i g. 2 b a section through the in F i g. 2 a shown engine,

F i g. 3a details of the sequence generator driver circuit used in the block diagram of FIG. 1,

3b shows a timing diagram of the circuit arrangement according to FIG. 3 a,

F i g. 4 is a block diagram with details of the in the block diagram of FIG. 1 used occasion and running logic,

F i g. 5 shows a timing diagram of the circuit arrangement according to FIG. 4,

6 is a block diagram with details of the in the block diagram of FIG. 1 used Stop logic,

F i g. 7 is a timing diagram of the circuit arrangement according to FIG. 6,

F i g. 8 is a block diagram with details of a differently designed stop circuit,

F i g. 9 shows a timing diagram of the circuit arrangement according to FIG. 8,

10 is a block diagram for the step drive of an induction motor,

11 shows a timing diagram of the circuit arrangement according to FIGS. 10 and

12 shows another block diagram for the step drive of an induction motor.

The pulse generator 20 generates a series of pulses with a relatively constant one without interruption Repetition frequency, and each pulse potentially represents a movement of the stepper motor When the motor is to be started, a start signal is sent to the stop-start gate circuit 21 supplied which the supply of pulses both to the binary pulse counter 22 as also allowed to the start and run logic circuit 24. The pulse counter 22 has several counting stages, one of the higher counting stages is coupled in such a way that it switches off the gate circuit 21 by applying a stop signal, which also resets the pulse counter itself. A relatively low counter stage of the pulse counter 22 is connected so that it is the logic circuit 24 starts up while a relatively high counting level is switched on. that they are the logical stop circuit 25 actuated.

Fig. La shows one of several possible start

7 8

Stop synchronization or gate circuits that have reached the desired synchronization speed as gate circuit 21 in Fig. 1 or in the others, the circuit arrangement 24 has its task Fulfills and simply derives the impulses from the guidance examples below to be described in detail below of the invention is useful. rator 20 directly to the OR circuit 27. This To ensure that the inventive 5 feature of the invention will be better understood Control circuits are working properly, the more detailed description below may refer to it often prove to be important, the forwarded im- Figs. 4 and 5.

pulse precisely to synchronize, in particular the logic stop circuit arrangement 25 is the other when through the leading edge of the further through a relatively high counting level of the pulse counter Conducted pulses of the time defined are actuated io 22, and this level could be the same high to which a later operation will take place. The or slightly lower than the count level that the The circuit shown in Fig. la leads to a start gate circuit 21 which has supplied the stop signal. the signal to terminal 60 from the pulse generator circuit arrangement 25 has the purpose of temporal rator to terminal 61 reaching clock signals to the correspondingly controlled pulses at the end of the Im output 62 to introduce further without regard to the temporal pulse train, the by on and off position of the start signal. Your transmission of a train switching the gate circuit 21 has been generated so full clock pulse begins with the first that the rotor of the motor 29 is almost the speed Clock pulse, which has reached zero after the occurrence of the signal, if its physical orientation terminal 60 starts and ends with the last im- the corresponding to the desired step position, pulse that begins before the start signal drops. 20 Several possible arrangements for realizing the That is, the output signal at terminal 62 rises. Circuit arrangement 25 is described below. if the clock pulse at terminal 61 and the connection with the description for F i g. 6 to 12 Start pulse at terminal 60 both a high signal - discussed.

have level, but only if the start signal as Fig. 2 shows simply and symbolically a motor had risen for the first time. Therefore, the output 25 embodiment, which can be controlled by the inventive signal at terminal 62 only at the beginning of a clock circuit arrangement. First of all, let the pulse increase and only decrease when the indicates that both the one shown in FIG. 2 ge-clock pulse drops at terminal 61, whereby the motor as well as the sequence driver switch is safely shown * that whole clock pulses are routed out of Fig. 3 only as examples for the purpose of. Of course, after starting 30 an understanding of the invention,
signal at terminal 60 no further impulses. 2 a illustrated engine is an engine that produces. A reverse output with permanent magnet rotor and synchronous inductor output signal is generated at terminal 68. The start-up of the switch is characterized by a toothed rotor device of FIG. 1 a is carried out by a circuit of the locking type with a pronounced pole in the form of a permanent magnet locking type (not shown), which controls the rise of the 35 and a toothed stator with a pronounced pole, start signal Terminal 60 in response to a toggle signal around which stationary coils are wound. A act effected and the start signal at terminal 60 in the case of the high counting motor mentioned above for the counter 22, which was used neutrally together with the invention, had a rotor 30 with 50 teeth, which could drop out. The synchronization or Tor- rend in the poles 32 to 39 on the stator 48 teeth circuit arrangement of Fig. La merely represents a 40 milled. On the stator poles of the motor embodiment of an arrangement for carrying out the two-wire were windings only start-stop operation is for the poles 32, 34 and 38 _S 36 are shown. After the logic circuit arrangement 24 such windings are also located on FIG. 1 has been energized by the pulse counter 22 the poles 33, 35, 37 and 39. One is applied to the terminals and receives pulses from the gate circuit 21, 45 ⁴ O and 41 applied voltage flows through the inner it enables the application of a first pulse to most coils the poles 32, 34, 36 and 38 which are the OR circuit 27 which winds this pulse to the that the poles alternately forwards north and sequence driver circuit 28 which are south poles, ie, through one in the terminals 40 in turn the windings of the motor 29 step and 41 input signal could feed the poles 32 switching currents. Then the logic switch 5 ° and 36 for the rotor 30 to Nofdpolen and the processing arrangement 24 for a short period poles 34 and 38 to be made to south poles or no further pulses from the gate circuit 21 reversed.

more to get to the motor 29, after which the pulses. Terminals 42 and 43 are connected to another at the same repetition rate as the series of interconnected coils Generator 20 are generated, 55 bonds are applied, which are located on the same poles as be able. Instead of this, it is also possible to use character pulses connected to terminals 40 and 41, from the logic circuit arrangement 24 in from the symbolic representation of FIG. 2a the way that the drivers for the can be seen that the terminals 42 and 43 are connected to the motor 29 are wound by pulses with increasing re-closed coils in such a way that they the fetch frequencies are excited until the frequency 60 poles one of the terminals 40 and 41 verder Pulses from the pulse generator 20 reach the bonded coils of opposite magnetization is. With this arrangement, the motor 29 will give. If a signal is first sent to terminals 40 an initial speed, which is fed below and 41, so that the pole 32 as the north pole the speed that the repeat appears, and then disconnected and the clamps frequency of the pulse generated by the generator 20 65 42 and 43 supplied with the same polarity, erpulse corresponds to, but eventually runs with one, the pole 32 appears to the rotor 30 as the south pole. Act speed, The two sets of coils on each pole are responsible for the generation of the generator 20 th pulses. After the motor 29 is wound together, but at opposing

th ends excited. This arrangement has the advantage that current conductors effective in one direction, such as z. B. transistors can be used for direct excitation of the coils without switching is necessary. Such coil arrangements are called bifilar windings. The engine shown here is considered a two-phase motor, since the coils connected to terminals 40 to 43 are considered to be the first phase, while coils of this type, which are related to poles 33, 35, 37 and 39 connected to terminals 44, 45, 46 and 47 are referred to as the second phase.

The in F i g. 2 a shown engine is in F i g. 2 B shown in section. There you can see that the rotor consists of a permanent magnet 48 on which Ends of caps 49 and 50 are put on. The rotor teeth are shaped in the caps 49 and 50, each with exactly the same number of teeth, but with such an application of the Caps on the magnet 48 that the teeth on one cap relative to those on the other cap are axially offset. So for any given combination of energized coils on the stator, the Runner 30 a stable position. If z. B. terminals 41, 43, 45 and 47 of FIG. 2 a grounded and a signal would be applied to terminals 40 and 44, the rotor would assume a position. By de-energizing terminal 40 and energizing terminal 42, the effective magnetic circuits would shifted around the stator, and the rotor 30 would thereby be in a new stable Brought location. Through continued manipulation of the excitation signals fed to the coils of the stator the magnetic field can be made to rotate once around the stator, which has the result that the rotor is moved by one tooth pitch. As shown in FIG. 2 b it would be the cap 49 effectively a north pole in its entirety and the cap 50 effectively a south pole in its entirety.

F i g. FIG. 3 a shows a simple sequence driver circuit for controlling the operation of a motor of the type shown in FIG. 2. A series of pulses P occurring at regular intervals is fed to the bistable flip-flop 51, whereby it is flipped from one conductive state to the other when each pulse rises in the train P. The bistable flip-flops 52 and 53 in turn each change their conducting state in response to increases in the respective conducting states of the flip-flop 51. Drivers 54 through 57 then speak, connected in the manner shown to terminals for the motor of FIG. 2 a are connected to the conductive states of the trigger stages 52 and 53. From Fig. 3b it can therefore be seen that for every four pulses in the pulse train P, the drivers have run through a complete cycle of combinations and have returned to their original conduction state and thereby the rotor 30 of the motor of FIG. 2 a has been moved forward by one tooth spacing. The engine shown in FIG. 2 and the engine shown in FIG. Sequence driver circuits shown in Fig. 3a are illustrated as examples only.

The timing diagrams which aid in describing the circuit operation are general Output voltage level for the blocks or lines, their reference numerals along the left edge of the diagrams.

A detailed block diagram of a preferred exemplary embodiment is shown in FIG. 4, and the timing diagram for the circuit arrangement of FIG. 4 is shown in FIG. First is the binary Pulse counter 71 has been supplied with a clear signal by which all its counting stages are cleared and by which also the latch circuit 72 is made ineffective, the effect of which in a There is a decrease in the voltage on line 73 and an increase in the voltage on line 74. the Pulse generator 70 generates an uninterrupted train of pulses at regular intervals that the gate circuit 75 are fed through which they only get after a start signal on the line 76 has been given. When the line 76 is energized, the pulses from the generator 70 appear at the output of the gate circuit 75 and the pulse counter 71, the inverter 77 and the AND circuit 78 forwarded. The first pulse passed by the gate circuit 75 does not reach the Motor 84, since line 73 is not energized and therefore AND circuit 78 is not prepared. How out the timing diagram of FIG. 5 can be seen, however, causes the fall of the first pulse from the Gate circuit 75 that the first stage of the pulse counter (stage 80) is excited, whereby the AND circuit 79 is prepared, which in turn has been prepared by the excited state of the line 74. Hence the reverse pulse from circuit 77 causes the generation of a pulse by the AND circuit 79, which in turn by the OR circuit 81 arrives and energizes the sequence driver circuit 82 and ultimately the motor 84. the The first pulse from the OR circuit 81 (according to FIG. 5) is thus fed to the motor.

When the next output pulse from the circuit 75 occurs, the stage 80 is switched off and energizes stage 85, causing the next inverted pulse to pass through the AND gate 79 is prevented. The third pulse, however, re-energizes stage 80, creating the AND circuit 79 is prepared again and therefore the generation of the second excitation pulse at the output the OR circuit 81 is allowed. A period has now expired that is twice as long as that Period of the pulses generated by the pulse generator 70. The appearance of the fourth output pulse the gate circuit 75 is sensed by the counter stage 86 which the latch circuit 72 sets and thereby turns off AND circuit 79 and prepares AND circuit 78. Therefore, the Next output pulse of the gate circuit 75 through the AND circuit 78 to the OR circuit 81 arrive in a time period which is one and a half times the time period of the pulses from the generator 70. Thereafter, the latch circuit 72 remains set so that the AND circuit 78 prepared and the AND circuit 79 switched off and the pulses from the Gate circuit 75 continuously through OR circuit 81 into the sequence driver circuit of the motor. This arrangement enables a stepper motor to be set to the desired To accelerate the speed (that of the period of time generated by the generator 70 Pulses), without any synchronous speed after the synchronous speed has been reached Vibration occurs. It is also possible to use the

Motor 84 to operate at a synchronous speed (corresponding to F) which is above its overload frequency is by simply changing the time period between the first two output pulses of the OR circuit 81 is set so that the repetition frequency therebetween is below the overload frequency located.

Of course there are several different arrangements for achieving the same result within of the in the embodiment of FIG. 4 described the scope of the invention. If z. B. a relatively large load is coupled to the motor, but with the two-pulse accelerator arrangement according to FIG. 4 does not accelerate satisfactorily, the acceleration pulse period, which is fed to the engine, can be extended, and the number of pulses and pulse periods before the operating speed is reached can be increased be to get a smooth acceleration to the synchronous speed to guarantee. This can be achieved by a number of means, such as: B. by using additional channels accordingly that included in AND circuit 79 or through the use of gated monostable Trigger circuits or gated combinations of AND circuits or the like.

The overall operation of the circuit according to FIG. 4 can be used as a binary controlled pulse generator describe with variable frequency, which has the ability to accelerate nonlinearly bring the motor and its load to the synchronous speed. Therefore some are possible Alternatives to the one shown in FIG. 4 shown arrangement z. B. controlled by variable voltages Multivibrators, time delay devices with sequence control and the like with suitable gate control arrangements. Further, the pulse generator and drivers 82 could be directly related to the in Fig. 3, and the actually driven motor 84 could be shown directly in Relationship to that shown in FIG. 2 can be set.

An embodiment of the invention for stopping a stepping motor without vibration after performing a predetermined number of steps is shown in FIG. 6 shown. In this embodiment, pulses with regular repetition frequency from an oscillator or pulse generator have been passed through the start-stop gate circuit 90 to be counted by the binary pulse counter 91, and are also fed through the OR circuit 92 to the sequence driver circuit 94 to energize the coils of motor 95. After the pulse counter 91 has counted enough pulses, a pulse is generated at its output which blocks the gate circuit 90 and puts the monostable multivibrator 96 into operation. In the one shown in FIG. 6, the pulse counter 91 is arranged so that the gate circuit 90 is switched off two pulses before the last desired step position. If the last pulse applied to the motor was the last for the gate circuit 90 in the timing diagram of FIG. 7, in the best case the rotor of the motor 95 would vibrate violently around the desired last step position due to inertia and could itself continue to the next stable step position, which would be extremely undesirable.

However, if the circuit arrangement of FIG. 6 is used to generate the last two pulses of the pulse train required to advance the motor, the motor can be stopped at the desired point without vibration. In detail it behaves as follows: By the drop in the output signal of the pulse counter 91, the monostable multivibrator 96 is excited so that it generates a single output pulse which is variable in width, which is indicated by the double-headed arrow 96 in the pulse diagram of FIG. 7 is shown. The end of the pulse from the one-shot circuit 96 actuates both the one-shot circuit 96 and the one-shot circuit 98.

The output of the monostable multivibrator 96 is connected directly to the OR circuit 92 in order to excite the coils of the motor with a pulse which is delayed from the repetition frequency of the previous pulse train. The pulse generated by the circuit 97 thus decelerates the rotor of the motor 95. After a period of time that the pulse at the output of the monostable multivibrator 98 needs to drop (which can also be changed, as indicated by a further double-headed arrow) the one-shot multivibrator 99 is energized in order to supply the OR circuit 92 and thus the motor 95 with the last stepping pulse. The last pulse thus supplied by the circuit 99 corresponds to the desired step position. By simply observing the running of the rotor of the motor 95 with an oscilloscope, the width of the monostable flip-flops 96 and 98 can be adjusted in such a way that the monostable flip-flop 97 applies a deceleration pulse that is sufficient to precisely turn the rotor Bring to a standstill when it reaches the desired step position, at which point in time the monostable flip-flop circuit 99 supplies the motor with the last pulse exactly in the desired position without vibration. So if 100 pulses corresponded to a predetermined stepping operation and the arrangement of FIG. 6 should be used, the pulse counter 91 would count up to 98 pulses and then block the gate circuit 90. Thereafter, the monostable multivibrators 96 and 97 would then generate the 99th pulse and the monostable multivibrators 98 and 99 in conjunction with the monostable multivibrator 96 would generate the 100th or last pulse.

The in F i g. 6 could also be configured with a single pair of monostable multivibrators, such as B. 96 and 97, be operational if the engine vibration when stopped is low enough is to allow for such an arrangement, and additional stages for a motor with greater inertia of delayed pulses may be required. So the engine can run from a relatively fast run shut down in the shortest possible time without vibration and in a relatively simple way to maximum operation can be set.

Furthermore, the circuit arrangement of FIG. 6 is particularly suitable for combination with the circuit in FIG Fig. 4 shown circuitry to provide almost complete control of a high speed to ensure that the stepper motor is running. Indeed, different parts of the both systems will be almost identical. The operations of the monostable circuit in

the embodiment of FIG. 6 and the operations illustrated in FIG. 4 as well as those of Figures 8, 10 and 12 all using AND circuits put into practice with multiple inputs and clocks or counters.

F i g. 8 illustrates another embodiment of the invention for stopping a stepping motor at the end of a stepping process. As in the other arrangements, the pulse generator generates 100 pulses with regular repetition frequency, which occur under normal operating conditions the gate circuit 101 arrive and are counted by the pulse counter 102.

In addition, the output pulses of the gate circuit 101 excite the sequence generator circuit 104, which in turn turns various combinations of driver circuits 108-111 on and off will. When one or more relatively high counter steps are excited in the pulse counter 102 the one-shot multivibrator 105 is actuated. From the timing diagram of FIG. 9 it can be seen that when the penultimate pulse occurs before the desired stepping position by the pulse counter 102 the monostable multivibrator 1OS is put into operation.

When the output pulse of the one-shot circuit 105 falls, the one-shot circuit becomes 106 and sends a pulse to all driver stages 108, 109, 110 at the same time and 111. Since these drivers are based on the methods shown in FIG. 2 work shown bifilar windings, thereby arise from each other opposing magnetic forces between any two coils on any pole, whereby the Coils are effectively grounded as seen from the rotor of the motor. The permanent magnet rotor of the motor 114, which has hitherto been driven as a motor, is therefore suddenly with respect to the field coils effective as a generator and is subjected to a retarding or decelerating torque. While the one-shot multivibrator 106 energizes the driver circuits, the pulse train generator has 104, which is in no way affected by the operation of the monostable multivibrators 105 and 106 has been, the last output pulse of the gate circuit 101 to turn it off. The order generator so saves the last pulse from the gate circuit 101 to the driver combination accordingly to excite, which corresponds to the last step position after the fall of the output pulse from the monostable multivibrator 106.

By observing the motor operation with an oscilloscope, the monostable multivibrators 105 and 106 are set so that by the above-mentioned generator action of the rotor of the motor 114 is decelerated to the speed zero when it reaches the last step position, and at this point the generator 104 is effective again, so that the rotor without vibration in the desired step position is locked. By taking the width of the pulses from the monostable Making flip-flops 105 and 106 adjustable gives the best control range for convenience of the scope alignment process, but each of these pulse widths could also vary depending on the circumstances be determined.

This embodiment is an advantageous improvement over the known method to stop a motor rotor, in which its coils are short-circuited, and as a generator are effective. Such an operation is manual with the known methods or by analog servo systems (with closed loop control) which are incompatible with digital operation are. By energizing all drivers 108 to 111, the coils of all stator windings are through one low impedance short-circuited together, and therefore a dynamic braking effect arises after

ίο type of generator excited by permanent magnet, because the opposing excitation of the two-wire coils results in zero net torque on the rotor generated. Compared to the stop circuit of FIG. 6, the circuit arrangement of Fig. 8 especially for a relatively slow stepping motor operation, z. B. when the maximum uncontrolled or undamped vibration is less than is a motor step.

Fig. 10 shows a system for operating a synchronous Induction motor similar to that in F i g. 2 shown in step-by-step fashion to produce an intermittent Movement without generating vibration. The system can advance the motor one step at a time or a sequence of individual steps of the motor. The system shown in FIG causes the step movement of the motor by first a first acceleration pulse, then a brief reversal or braking pulse and finally the forward pulse again at exactly the point in time be applied when the motor has reached step position, in such a way that the motor instantaneously at least at the step position corresponding to each input pulse without vibration can be adhered to. Furthermore, each step is essentially independent of the preceding one and later operations. It is only necessary that the next following operation not occur before the chronological sequence of processes for the immediately occurring step-by-step movement is a step-by-step cycle was able to complete.

The following description of the circuit arrangement of Fig. 10 is based on the timing diagram obtained from Fig. 11 to facilitate understanding of the operation. For the components are arbitrary voltage levels at time Γ0 have been assumed. The inverter circuits of FIG. 10, such as E.g. 121, 125, 132 and 133 are only shown because the diagram illustrates a circuit which is designed to work with monostable multivibrators, which are timed negatives Generate pulses in response to negative input pulses. When using monostable multivibrators, which generate positive output pulses from negative input pulses would be the inverters not mandatory.

A negative input pulse P supplied to the monostable multivibrator 120 sets the system in motion. The output pulse generated by 120 is reversed by the inverter 121 and fed from there to the bistable multivibrator 122 and two monostable multivibrators 123, 124. At the beginning of the pulse from the monostable multivibrator 120 and the inverter 121, the bistable multivibrator 122 changes its conduction state, so that the voltage level of the line 127 rises and that of the line 128 falls. This is passed on through the negative OR circuit 130 and the inverter 132 and causes the bistable multivibrator 134 to

Change in their conduction state so that the voltage on line 136 rises and that on line 137 falls. As a result, the driver 140 is switched off and the driver 141 is switched on and the beginning of the time period Π is marked. When the pulse at the output of the inverter 121 falls, the monostable multivibrator 123 generates a pulse which is fed to one input of the OR circuits 130 and 131. Since the line 127 now has a high voltage and the line 128 a low voltage, the pulse from the monostable multivibrator 123 passes through the OR circuit 130, but not through the OR circuit 131. The pulse from 123 is therefore passed through the OR circuit. Circuit 130 and the inverter 132 forwarded and causes the bistable multivibrator 134 to change its conduction state, whereby the voltage on line 136 drops and that on line 137 rises. As a result, the driver circuit 140 is switched on and the driver circuit 141 is switched off and the end of the time period T1 and the beginning of Γ 2 are marked.

The trailing edge of the output pulse from inverter 121 actuates not only monostable multivibrator 123 but also monostable multivibrator 124. The output pulse from 124 has activated monostable multivibrator 126 after passing through inverter 125. Since the OR circuit 130 can let the output pulse from 126 through, it arrives at the bistable multivibrator 134, which signals the end of the time T1 and increases the voltage on line 136 and lowers the voltage on line 137 while switching its line state again. During the time Π an acceleration pulse was applied to the rotor of the motor and caused it to start moving. During the time Tl the motor reverse torque has been applied and has slowed him in his approach to the desired step position or slowed. At the beginning of time T3 , the runner was approximately in the desired step position and was locked by the line pulse level that had caused the first acceleration. At time T 3 , the runner is therefore in a stable, non-vibrating step switch position.

When a second negative pulse P is applied, which marks the beginning of the period Γ 4, the bistable multivibrator 122 is switched over, as a result of which the voltage level of line 127 is lowered and that of line 128 is increased. As a result, no further negative signals can pass through the OR circuit 130, but the OR circuit 131 can pass all subsequent pulses. In addition, the bistable multivibrator 135 senses the change in the conduction state and changes its own conduction state, so that the voltage on line 138 rises and that on line 139 falls and therefore the driver 143 becomes conductive and the driver 142 is switched off. During the time periods Γ4, T5 and T6, the operation of the circuit arrangement consisting of the elements 131, 133, 135, 142 and 143 is essentially the same as the operation of the elements connected to the OR circuit 130, as described above.

The third negative transition in the pulse P causes the beginning of the third cycle, which operatively corresponds to the time periods Tl, Tl and Γ3, except that the line voltages of the drivers 140 and 141 (controlled by the line voltages 136 and 137) are reversed. This third cycle comprises the time periods T1, T8 and Γ9. It should be noted that stable step positions during times T3, T6 and T9 are reached and would be achieved in the time T12, at which time a complete cycle would be completed. In addition, times T3, T6, T9 and Γ12 correspond directly to each pulse applied to the system.

A table now follows, from which the above-described mode of operation of FIG. 10 emerges and which indicates the respective torque that the rotor of the motor 145 for each of the specified periods is granted. The table shows a full step cycle for the motor.

time step Rotor torque 140 Trei
141 ber
142 143 TO
Tl
Tl 0 Standstill
Forward
Backward ONE
OUT
ONE OUT
ONE
OUT ONE
ONE
ONE OUT
OUT
OUT T3
TA
TS 1 Standstill
Forward
Backward OUT
OUT
OUT ONE
ONE
ONE ONE
OUT
ONE OUT
ONE
OUT Γ6
Tl
T8 2 Standstill
Forward
Backward OUT
ONE
OUT ONE
OUT
ONE OUT
OUT
OUT ONE
ONE
ONE T9
TlO
TU 3 Standstill
Forward
Backward ONE
ONE
ONE OUT
OUT
OUT OUT
ONE
OUT ONE
OUT
ONE TU 4th Standstill ONE OUT ONE OUT

By setting the monostable tilt time control for the vibrationless step circuits 120, 123 and / or 124 in the monitoring circuit of the motor 145 is achieved. The observance of the reaction of the motor to an oscilloscope input pulse P could be an arbitrary or a phenschirm, the circuit of FIG.

209 582/65

pulse repetition frequency determined by time which is necessary to complete the timing sequence discussed above. This timing sequence for a particular system is a function of the parameters involved, e.g. B. the system inertia, the friction, the motor current and energy, the load and so on.

The circuit arrangement shown in Fig. 10 is arranged so that the response of the timing circuit and control logic circuit is relative is independent of the particular set of coils that is switched. That is, the output pulses of the monostable multivibrators 123 and 126 have the same timing, regardless of whether the stator coils connected to the drivers 140 and 141 or those connected to the drivers 142 and 143 connected have been switched. In practical applications, the coil circuit parameters are seldom exactly the same, and occasionally the differences could become so great that minor vibrations causes when the stepping position for a specific coil or specific coils will.

If the vibrations caused by the lack of uniformity in the coil circuit are not permitted, a system similar to that shown in FIG. 12 is similar to that shown. If the controlled stepper motor Two-wire windings would be used in the magnetic circuits with respect to uniformity insist on every single stator pole. But even in two-wire wound motors there are different ones other factors that could cause the lack of uniformity in the motor circuit, such as z. B. one or more missing turns on one or more coils or fluctuations in wire resistance within each winding or differences in the characteristics of the magnetic circuits or the like. If the lack of uniformity is not a significant factor, that shown in Fig. 10 will suffice System. Otherwise the system shown in FIG. 12 must be used. Since the in F i g. 12 circuit arrangement shown, apart from having two different timing circuits for each set of two-wire windings 10, will operate in the same way as the circuit shown in FIG Fig. 12 is not described here. Suffice it to say that you can see how the engine works on one Oscilloscope screen while the monostable flip-flops 155, 157, 165 and / or 167 operated by the first flip-flop 150 are set to be at each Stepping eliminate any vibration.

The invention allows several arrangements for the necessary timing operations To perform control of a stepper motor. For example, combinations or arrangements can be made are used by counters to measure the temporal

ίο to achieve control, or different combinations of clock generators, pulse counters, AND circuits, OR circuits, interlock circuits and the like The single or combined control systems shown and described above are included Much less effort to manufacture than other control systems for operating stepper motors. In addition, the control systems discussed here have the great advantage that they can be used by Applications controlled by digital computers are suitable because they are digitally structured and in the manner of an open one Work in the control loop.

A stepping motor controlled by the invention can be switched over in a relatively simple manner (i.e. rotated in the opposite direction). For example (Fig. 3a) could be the output lines are switched from the bistable multivibrator 52 so that they the drivers 56 and 57 control, while the output lines of the flip-flop 53 could control the drivers 54 and 55; this could be achieved fairly easily by a relay or a simple switching arrangement, thereby allowing the stepper motor to rotate in either direction. Another arrangement which could advantageously be used to reverse the direction of rotation exists in that a two-pole changeover switch in the output lines of the bistable flip-flop 51 (F i g. 3 a) is used to control the outputs of the flip-flop 51 depending on the desired direction of rotation to be connected accordingly with the bistable flip-flops 52 and 53. Switching would be preferred by logical AND and OR circuits to achieve high operating speed reach. Although the stepper motor described in connection with the invention is a two-phase Motor is, the invention is of course not limited to such an operation, but can also serve to control any multi-phase motor. The description is based on the NOR logic.

For this purpose 2 sheets of drawings

Claims (1)

Patent claims: 1. Circuit of an open control loop for digital control of the running characteristics of a synchronous induction motor of the stepping motor type with a the sequence of excitation the circuit that determines the stator windings, the drivers connected to the stator windings has, with further digital switching elements for influencing the timing of the pulses for the Excitation of the stator windings and with a pulse generator that has a stop interlocking device the order of excitation of the individual stator windings of the induction motor determining circuit supplies pulses which are blocked or released when the corresponding signal is received, whereby the through the Drivers amplified pulses in addition to the stator windings and also fed to a pulse counter connected to a brake circuit responsible for stopping or decelerating is, characterized in that one for starting or running the induction motor responsible logic circuit (24) one with the one on the binary pulse counter (71) connected output of a gate circuit (75) connected inverter circuit (77) has, the output of which forms the input of an AND circuit (79), the second input of which with the lowest counting stage (80) of the pulse counter (71) and its last input with the OUT output (74) of a latch circuit (72) is connected, the IN output of which (73) is connected to another AND circuit (78), the other input of which is connected to the aforementioned Output of the gate circuit (75) is connected that the ON input of the locking circuit (72) to a low counting stage (86) and the OFF input of the latch circuit (72) to the clear line of the pulse counter (71) is connected and that the outputs of the two AND circuits (75, 79) with a OR circuit (81) are connected, the output of which is connected to the order of excitation the stator windings of the induction motor determining circuit (82) is connected, wherein the pulse counter (71) is switched so that from the second counting stage (85) before being applied of the next higher counting level, a pulse is applied to the lowest counting level (80) and that those responsible for stopping or decelerating the induction motor logic circuit (25) from one of the size of the speed or the moment of inertia corresponding Number of the highest counting level of the pulse counter (91) connected downstream, to each other parallel pulse delay devices (96 to 99), each of which is one different pulse delay and adjustable, if necessary different pulse lengths generated and that these delay devices connected in parallel are the inputs of the logic circuit responsible for the sequence of energization of the stator windings (94) upstream OR circuit (92) büden. 2. Circuit according to claim 1, characterized in that the pulse delay devices from a first monostable connected to the highest stage of the pulse counter (91) Toggle circuit (96) with adjustable pulse duration exist, the output with two further monostable multivibrators (97, 98) connected in parallel are connected, of which the one (97) directly to the said OR circuit (92) and the other (98), the pulse length of which is adjustable via a fourth monostable multivibrator (99) with the aforementioned OR circuit (92) is connected. 3. A circuit according to claim 1 with a two-phase induction motor on the stator coils two windings generating opposite polarity in their energized state are arranged whose adjacent pole pieces each belong to a different phase and one in each of the two windings of the consecutive pole pieces Phase alternately have opposite winding directions and the sequence of excitation the phase-determining circuit of the winding groups is a bistable multivibrator, the outputs of which are connected to a driver stage either directly or via logic switching elements are, characterized in that the highest counting level of the pulse counter (102) has two monostable flip-flops (105,106) are connected in series that the output of the second Flip circuit to all with the the sequence of energizing the stator windings of the induction motor determining logic circuit (104) connected drivers (108 to 111) and that the pulse lengths of said monostable multivibrators are set so are that the pulse of the last of the two monostable flip-flops mentioned has dropped out before the one that acts on the highest counting level and also of the circuit (104) supplied pulse energizes the corresponding driver. 4. A circuit according to claim 3, characterized in that each of the two is the drivers bistable flip-flops (134, 135) connected directly upstream via a negative OR or NOR circuit (130 or 131) to the two outputs of the receiving control pulses further bistable flip-flop (122) is connected that each has a further input of the two negative OR circuits (130, 131) together to a further monostable multivibrator (123) connected, which sends the same control pulses as the last mentioned bistable multivibrator (122) receives and determines the end of the acceleration period, and that a further input of the two said negative OR circuits (130, 131) together with two connected in series fourth and fifth monostable multivibrators (124, 126) is connected, of which the first (124) receives the same control pulse as the last mentioned bistable multivibrator (122) and that the last (126) of the two series-connected monostable flip-flops (124, 126) determines the end of the delay period. 5. A circuit according to claim 3, characterized in that each of the drivers of the winding groups of one phase to one OR 3 4 Circuit is connected so that the two input drive wheels are moved further depending on the number of gears of each of the two OR circuits control pulses the film is connected to a certain distance to an AND circuit. Such stepper motors are used so that one input each of two of these four ANDs also largely for the drive of magnetic circuits to a common inverter circuit tapes, cards, paper tapes and the like.
In the construction of such stepper motors for the operation of one of the two AND drive rotating elements mentioned, there are, however, circuits at the one output of a further difficulty. One of these difficulties is the direct bistable flip-flop (151) and the second tendency of the rotor of this motor to vibrate after its input of the other of the two mentioned io shutdown. This oscillation in the AND circuits at the other output, the idle state, causes the rotor and the bistable flip-flop (151), known as the load inertia, to produce connected forces. In applications for the exact sen it is that one input of the other two further movement of a tape or a card is AND circuits at the output of a further circuit which leads to the aforementioned input circuit, however, this settling into the idle state is not permitted, and likewise If the time required to achieve the monostable multivibrator (157) is unsustainable, it is concluded that the other input of the one. Furthermore, it is often difficult to operate stepper motors of the two last-mentioned AND circuits at relatively high speeds With one output of the above-mentioned bistable synchronous induction motors, the two last-mentioned AND switches can be used with a relatively flip-flop (151) and the other input of the two last-mentioned AND switches can be used as stepper motors the stated speed below the maximum of the motor speed bistable Ki ppstufe (151) is connected, that the speed at which a drop for given loads to the monostable multivibrator (157) is observed in. In the torque-speed series with an inverter circuit (156) and a diagram for a specific load, this fourth monostable multivibrator (155) is referred to as a fall-off point, which is the output of one of the control pulses (F) sensitive point which the engine falls out of step. At the beginning of the fourth bistable multivibrator (150) the synchronous motor has one whose other output is connected to the input speed, below which it is not connected to any of the first-mentioned bistable multivibrators (151) 30 external load for given current field time constants and that the both drivers that start up again when the motor is stopped and the second phase is connected to a similarly structured circuit arrangement with pulses of a frequency equal or greater, the drop-off frequency of which is re-energized,
Both inputs with the fourth bistable multivibrator (150) 35, which receives the control pulses (P) A limitation of the dropping frequency is possible, by adding resistors to the stator winding opposite the same inputs, whereby the motor time constant is changed and the circuit arrangement assigned to the first phase is changed an undesired lowering of the voltage. Engine power results. To get around this, the motor had to be operated below the drop frequency. 40 or one had the repetition frequency of the dem The pulses supplied to the motor are increased from below the drop-out frequency to beyond, whereby The invention relates to a circuit but manual or automatic electromechanical an open control loop for digital control niche control elements are necessary. Undesirable the running characteristics of a synchronous induction 45 th vibration was used in known arrangements motors of the stepper motor type with a series through mechanical damping devices and due to the excitation of the stator windings determine closed control loops. However, they are the circuit, the familiar stepper motors with the stator windings for use in has bound drivers, with further digital connection with digital computers, in which particularly Switching elements for influencing the time of the 5 ° more precision for compliance with specified positions Impulse for the excitation of the stator windings and lungs is required and in no case a Vi cannot be used with a pulse generator which may occur via a stopping at standstill. Locking device of the order of the It is the object of the invention to provide a functional Excitation of the individual stator windings of the induction-safe control system for stepper motors with tion motor-determining circuit delivers impulses, 55 low technical effort to create the which, when the corresponding signal is received, allows the engine to be locked or released despite the high engine speed are given, whereby the angular positions given by the driver are the smallest strengthened impulses in addition to the stator windings and angular tolerance in a very short time in a vibrating a pulse counter can be fed to bring it to a stationary standstill. In the solution those responsible for stopping or decelerating this task, the invention proceeds from the following Brake circuit is connected. known arrangements from: Stepper motors produce one of the number of Control pulses that cause an alternation of the current- 1. From an open-loop circuit cause the motor windings through which it flows, for digital control of a stepper motor dependent movement. Such motors are described in 65 (U.S. Pat. No. 3,124,732), which is one of the used to an increasing extent. One order of excitation of the stator windings its areas of application forms the transport of a defining circuit and with the stator film strip, with the driver connected by driving a tape windings.