DE2524447B2 - Device for monitoring and signaling the transition from alternating control processes - Google Patents

Description

The invention relates to a device for monitoring and signaling the transitions from alternating control processes in a control system with successively arranged controllers (series controllers), especially for constant control of electrical quantities.

The monitoring of the replacement of a control process by another new control process is at Systems with series regulators and not only these for the implementation of automatically running processes > agile as well as ensuring that control processes during a process during and through this replacement can be assigned according to the program. For example, here is the automatic three-hour charge of electrical accumulators (batteries) according to

it) of an IUI characteristic curve, where the Detection of the replacement of the second charging stage, charging with constant voltage, by the third charging stage, Constant current charging is important.

In a known arrangement for current-dependent regulation of the voltage of a consumer, such as for example a battery (DE-PS 15 38 690) with the help of a controlled rectifier is a release circuit used with diodes in the rectifier control circuit to make the battery voltage dependent from the charging current from constant regulation at a certain value to constant regulation on a other voltage value can be reversibly switched. In the control circuit is one of the Charge current derived to a desired one

2 ^r i separation current intensity adjustable constant counter voltage reduced direct voltage impressed. Furthermore, the control circuit branches via two shunt diodes to a voltage divider above the battery, of which the two specific ones are to be constantly regulated

J »Voltages as actual voltages in the control circuit are embossed.

A device for signaling the transitions from alternating control states, namely from Constant voltage to constant voltage regulation,

The known arrangement does not contain i ~> , but a signal for detecting the separation can be generated at each transition. The prerequisite for this signal generation is that it must be set to the separation point of the control characteristic, so that the signal generation cannot automatically take effect at any given separation point.

The invention is based on the object of a device for monitoring and signaling the initially specified type to create with which

< ^r > these transitions from alternating control processes exactly in relation to the control characteristic curve representing the control processes as a whole, i.e. the relevant replacement points of the control core line can be detected and processed into one signal each, although this signal generation cannot be caused by interference.

This object is achieved according to the invention in a control system with a series regulator by the im Patent claim 1 characterized features.

~>^Γ> An accurate detection of the release points of a control characteristic and a signal generating alone caused thereby is achieved a further embodiment of the invention as by the features characterized in Patent Claim 2 Characteristics.

'»It is also in accordance with a further embodiment the invention by the features characterized in claim 3 enables a specification of the each alternating control process can be set according to a program.

Is the signaling circuit as a result of the replacement of a control process by a new control process once switched on, according to a particular embodiment of the invention, the im

Patent claim 4 characterized features in each case according to the type of a backstop in the attracted relay Brought self-holding, from which it is only when switching off the DC voltage source feeding the monitoring device can drop again, or it is with the relay pulled in and locked also the alternating control process until the DC voltage source feeding the monitoring device is switched off maintain.

Advantages of the invention described are seen in the fact that they with respect to control characteristics Exact recording of transitions in alternating control processes with any changes or Changeover of the control characteristics is retained.

In the drawing, as an exemplary embodiment of the invention, a corresponding device for monitoring is shown and signaling in a series regulator for three-stage charging of batteries is shown and is described below.

Of the series regulator 1 for three-stage charging, the essential part of the controlled system with a voltage regulator 11 as a pre-regulator and a current regulator 12 as a slave regulator, which are arranged one after the other for the subordinate regulation, is shown in the drawing above. In the controlled system between the output of the voltage regulator and the nominal input II of the current regulator, one after the other, there are current limiting resistors 13 and 14, a coupling diode 15 polarized in the direction of the control flow, and at least two other ohmic resistors 16 and 17. The two regulators 11 and 12 each have an actual input I. and a setpoint input II. The control status of the series regulator is detected as direct voltage potential upstream of the coupling diode 15 and is fed to a first input I of a voltage comparator 22 of the monitoring device 2 via the ohmic resistor r 21 of a series delay element 21. A comparison voltage, which is derived from a regulated DC voltage of a DC voltage source G by means of an ohmic voltage divider, is fed to the second input II thereof. The output of the voltage comparator 22 is connected to the negative pole of the voltage source G via resistors 23, 25, a diode 24 and also via the base-emitter path of a transistor 31. The transistor 31 lies in a voltage divider, consisting of a collector resistor 32 and a resistor 33 with a diode 34, and also a Zener diode 35, connected to the voltage source G, and forms a switching stage 3 that is assigned to a Miller integrator 4.

In the voltage divider 32, 33, 34, 35, the transistor 31 receives a stabilized emitter potential above the potential of the negative pole of the voltage source G. The Miller integrator 4 is used as a time stage with a capacitor 41, which a discharge circuit with a large time constant with the high resistance Resistor 43 and a charging circuit with a low time constant with transistor 31 and a low-resistance resistor 33 'are assigned, which circuits are connected to voltage source G. The resistor 43 can be changed and exchanged for setting time constants of different sizes. The collector of transistor 31 is connected to the input of the Miller integrator. The output of the Miller integrator controls a transistor 51 located in a relay current 5 via an inverter 4 ′. In the relay circuit is the coil 52 of a relay to which mechanical contacts (not shown in the drawing) for sounding signal circuits are assigned. The relay circuit 5 j is connected to an unregulated DC voltage source C.

The controlled system of the series regulator 1 is behind the coupling diode 15 a selectable large DC voltage potential through a potentiometric potential-

Ki her 6 fed to the output of the voltage and Pre-regulator 11 her specific potential at the set input of the current and slave regulator 12 is connected to specify discrete nominal currents. The potential generator consists of a number in parallel

υ switched potentiometer branches 61, 62, 53, the fixed taps of which are combined via a breakaway diode 61 ', 62', 63 '. The branches connected in parallel are connected to G via a resistor 64 and a selector switch 65, by means of which a potentiometer branch and thus a specific DC voltage potential behind the diode 15 can be set.

In the following, the mode of operation of the device will now be explained using the example of monitoring and signaling

--3 sization of the between the control processes - charging with constant regulated voltage (second charging stage) and recharging with constantly regulated current (third charging stage) - described for three-stage charging of a battery. For the three control processes, IUI delivers

»'Always the current and slave regulator 12 a control voltage corresponding to one in the current controller by comparing the charging current actual value with a current setpoint generated control deviation. It is assumed here that the battery has the constant current I der

;> has recorded the first charging stage. In the second The charging level is then set to input II of the Sirom regulator a monotonically decreasing DC voltage potential from the output of the voltage and pre-regulator 11 fed via the coupling diode 15, which is in the

in voltage regulator by comparing the actual charging voltage value formed with a voltage setpoint specified for constant regulation of the charging voltage will. By means of the selector switch 65, the potential generator 6 is set to a potentiometer branch, e.g. B. 62, discontinued,

• n from the one via the associated separation diode 62 ' selected DC voltage potential is additionally fed to the controlled system behind the coupling diode 15. In this way, a corresponding charging current is selected at which the control process of the second charging stage

the third is replaced by the control process Charging stage with constant regulation of the selected recharging current.

If the DC voltage potential behind the coupling diode 15 falls below the falling DC voltage potential in the second charging stage

Vi is the additional potential supplied by the potential generator, then the diode 15 blocks the control influence of the voltage regulator 11 and at the same time also blocks the feed the additional potential to the output of the voltage regulator. The additional potential is that alone

hi target input of current regulator 12 supplied to the specification of the selected current setpoint in the third charging stage. On the other hand, since the voltage regulator 11 when entering the third charging stage receives increasing actual voltage values, so the DC voltage potential

■ · ■ · negative at the output of the voltage regulator. To the Detection of the transition to the third charging stage is now this potential drop in front of the diode 115 via the ohmic resistance r21 of the ballast RC element

21 is fed to the actual input 1 of the voltage comparator 22. The RC element 21 can be dimensioned for a default delay of a few seconds and is used to prevent undesired signal generation by means of the voltage comparator 22 in the event of brief, abrupt adjustments in the control system. By means of the voltage comparator, the potential drop registered in front of the diode 15 is processed into a negative control signal and fed via the switching stage 3 to the input of the Miller integrator 4 '", which is used to further delay the control signal the direct voltage from the voltage source C to the device via a series RC element 36, 37 connecting the positive pole and the base of 31 '""> connecting the device, so that the capacitor 41 is charged via the transistor 31 and the input of the Short-circuited transistor 4. The transistor is then turned on by a positive potential at the output of the comparator 22 in the first and second charging stages via the resistors 23 and 25 and the diode 24, and the capacitor 41 is thus kept charged until the negative control signal from the voltage comparator 22 arrives, which marks the transition from the - ^v > second to the third drawer level signaled. The negative control signal blocks the transistor 31 and the Miller integrator 4 is set to run, the capacitor 41 slowly beginning to recharge at G via the resistors 42 and 43. At the same time, a signal that slowly becomes negative is produced at the output of the integrator, with which the reversing stage 4 'is turned on and the transistor 51 of the relay circuit 5 is kept blocked.

The runtime of the integrator forms an additional ^r> time delay of the control signal. It is specified by different high-value resistors 43, which can be used in the discharge circuit at cc /. At the end of the running time the reversing stage 4 'is blocked, whereby the transistor 51 is turned on and · "· the transistor relay with the relay coil 52 is activated. This finally turns on a signaling circuit, whereby the transition to the third charging stage is displayed with a delay.

In the described monitoring and signaling device, the Miller integrator 4 is preceded by a further switching stage 7 with a transistor 71, which forms a type of backstop. The emitters of the transistors 31 and 71 are connected to each other, using a plug-in device 72, the collector of the transistor 71 can be connected to the output of the voltage comparator 22 via the resistor 23 or to the output of the voltage regulator 11 via the limiting resistors 13 and 14 of the controlled system. In the first case, the collector is also connected to the base of the transistor 31 via the resistor 25 and the diode 24. The base of 71 is connected to the output of the inverter 4 'via a resistor 73 and a diode 74. In the position ef of the device 72, when the transistor 51 is turned on as a result of a control process being removed from the output of the inverter, i.e. the signaling circuit is turned on, the transistor 71 is turned on, whereby the input of the integrator 4 is influenced in such a way that dai are attracted Transistor relay in self-holding), from which it can only drop off again when the DC voltage is switched off from the voltage source G. In the position e - ^ of the device 72, the collector of the transistor 71 is connected to the output of the voltage regulator 11 via the resistors 13 and 14. In this case the output of the voltage regulator is ineffective, the resistors 13 and 14 serving to limit the current. In the position e- g , when the transistor relay is pulled in and locked, the releasing control process is maintained until the DC voltage is switched off from the voltage source G.

Finally, it should be noted that the monitoring and signaling device described transitions able to detect between control processes regardless of the direction of the transitions, d. H. the The facility has the ability to address and signal reversibly.

1 sheet of drawings

Claims (4)

Patent claims: 1. Device for monitoring and signaling the transitions from alternating control processes in a control system with consecutive controllers (series controllers), in particular for constant control of electrical quantities, characterized in that at each two consecutive controllers between the output of the pre-controller (11) and the input of the slave controller (12) has a coupling diode (15) polarized in the direction of the control flow and the Control state of the system, detected as the DC voltage potential in front of this diode, one of the Replacement of a control process controlled by the pre-regulator into a signal converting voltage comparator (22) is supplied, which signal is delayed by a Miller integrator (4) as Control signal to a signaling circuit switching transistor relay (5) or directly to one Signal transmitter is supplied, and that behind the coupling diode (15) from a potential transmitter (6) DC voltage potential is supplied, which by means of a selection device (65) to one of the alternating control process controlling course is adjustable. 2. Device according to claim 1, characterized in that the detected control state of the system is fed to a first input (I) of the voltage comparator (22) via an ohmic resistor (r 21) of a series RC element ^ r21, c21) , whose second input (II) is supplied with a reference voltage derived from a regulated DC voltage source (G) and its output via resistors (23, 25), a diode (24) and the base-emitter path of a capacitor (41 ) of the Miller integrator (4) lying transistor (31) is connected to one pole of the voltage source (G) . 3. Device according to claim 1, characterized in that the potential generator (6) consists of parallel ohmic potentiometer branches (21, 62, 63) or voltage dividers, each of which contains an ohmic resistor and a Zener diode, the taps of which each have a separation diode (6Γ , 62 ', 63') are combined, and is connected to the DC voltage source (G) via a resistor (64) and a selection device (65). 4. Device according to claim 1, characterized in that a Miller integrator (4) is arranged upstream Transistor (71) when the signaling circuit is switched on, optionally by means of a contact device (72) each via at least one resistor (13, 25) either to the output of the pre-regulator (11) or to the base-emitter path of the The transistor (31) in the charging circuit of the capacitor (41) of the Miller integrator conducts current in parallel is switched.