DE2206022B2 - PROCESS CONTROL DEVICE - Google Patents

Description

The invention relates to a process control device for several main operating parameters and at least an additional operating parameter, consisting of operating parameter converters and a memory for the converted main operating parameters, the digital values corresponding to the main operating parameters a digital register for controlling an output signal controlling the process.

Process control devices are known in various designs. A major disadvantage with These control devices are the effort required to control several operating parameters. Thus, in a known device, the function of more than two operating parameters an output signal generated, a computer required (US-PS30 34 718).

From US-PS 34 30 206 it is known that there are pulse generators whose frequency of one Company size depends.

From DT-OS 16 73 560 it is known to use controllable delays in a process control system.

The invention is based on the object of providing a process control device of the type mentioned at the beginning create an output signal with little effort compared to the prior art of several operating parameters and thereby a high degree of resolution of the operating parameters guaranteed.

According to the invention, this object is achieved by

ίο that one in frequency depending on one or several operating parameters controlled pulse generator is provided, which after generating the Output signal supplies pulses to a logic, which these pulses after a predetermined delay time

to query the digital register which, depending on the memory content, determines the length of a control pulse for logic determines, forwards.

Because the two main operating parameters are kept ready for interrogation in a digital register while the other operating parameters are taken into account by the frequency of the interrogation pulses a comparatively simple control device is obtained. The resolution of the saved The main operating parameters are good because the delay in interrogating the digital register means that the Length of the output signal for a specific signal! is increased in the digital register.

The logic preferably has a counter. its input via a feedback AND link with the pulse generator and with the output of the output signal! delivering, from the digital register is connected to the control pulses triggered bistable circuit.

According to an embodiment of the invention include / to pulse generator a capacitor, which is through a Transistor can be charged, the control electrode current of which by a first secondary operating parameter and its Collector current at a certain control electrode current can be determined by a second operating characteristic, and a thyristor its cathode voltage by the charge of the capacitor and its control electrode voltage by a third Operating parameters are determined, with the charging of the capacitor through the transistor is terminated by switching on the thyristor discharging the capacitor.

The invention is described below using an exemplary embodiment with reference to the drawings explained in more detail. In the drawings is

Fig. 1 is a block diagram of the process control device and

FIG. 2 shows an exemplary embodiment for a generator for use in the process control device according to FIG Fig. 1.

According to the drawing, a process to be controlled requires an input in the form of a pulse, the duration of which determines the progress of the process, and it should be determined by the values of two operational variables that are assigned to the process. The control device has a diode matrix 77, consisting of 16 input lines 11a to 11p together with 16 sets of input lines 12a to 12p, each set of lines 12 consists of seven separate lines. The lines are through a Decipher 13 in a manner to be described according to the value of one of the operational variables excited. Another decider 14 serves according to the value of the other farm size in

yiner turn manner to be described to one of the 16 sets of switches 15a-15p which are 12a respectively assigned to 12p lines, the switches 15a serve to 15p to one of the sets cables 12a to 12p with a digital comparator 53 _z u connect . The lines 11 cross each of the lines 12, and there are connections between the lines via diodes empirically according to the process to be controlled. If a certain value is assumed for each of the two operating variables, one of the lines 11 is excited, and one of the sets of switches 15 connects one of the sets of lines 12 to the comparator 53. In the drawing, dots represent diode connections If the line 11a is energized and the decoder 14 actuates the switch 15a, the comparator receives a signal 1001000, with -tem I a period connection and 0 no connection. Correspondingly, if the line Ma Boch is always energized, but the switch 15p is switched on. the signal 1111111 received by the comparator 53. It goes without saying that, for the sake of simplicity, only four of the lines 11 and only two of the groups of lines 12 have been shown.

The manner in which the lines 11 and \ 2 are energized corresponding to the two operating quantities will be described in detail, but for the moment it is assumed that the comparator 53 receives a 7-bit input signal which provides the required output of the system.

any convenient, cyclically operable switch 45 is used to provide an input. which trigger a bistable circuit 46 when an output pulse is to arise from the system. The bistable circuit 46, after triggering, also serves to provide an input to a gate circuit 47 tu , which also receives an input from a pulse generator 48 which operates at a specific frequency. The system also includes a counter 49 and a gate circuit 51, but these parts are ignored for the moment and it is assumed that when the gate circuit 47 receives an input from the bistable circuit 46, it receives pulses from the generator 48 forwards to a counter 52. The counter 52 is connected to a comparator 53 which also receives the input from the matrix 77.

With the beginning of an output pulse, the generator 48 begins to deliver pulses to the counter 52 (with the counter 49 still being disregarded). When the display of the counter 52 is the same as is that of the input to the comparator 53, an output pulse is supplied to a counter 54, and At the same time, the counter 52 is reset by a reset line 21. This is repeated until the Counter 54 has received a certain number of input pulses. This arrangement enables Examine the input to the comparator 53 many times so that changes in the input are taken into account. The total time it takes for the counter 54 to trigger a specific number. determines the Length of the output pulse and of course depends on the mean value of the operating variables that the Comparator 53 receives, and when the required number of pulses have been received from counter 54, 6s are, the bistable circuit 46 is triggered, which terminates the output pulse. The cycle will then repeats the next time the bistable circuit 46 is triggered.

The task of the counter 49 and the gate circuit 51 is to introduce a fixed delay before the counter 52 is actuated by pulses from the generator 48. When gate 47 conducts, the counter must 49 contain a certain number of pulses before he is an input to the gate circuit 5i, and this then takes effect to feed the counter 52 due to the connection to the generator 48. A Another output from the counter 49 then blocks the gate circuit 47. The purpose of introducing a such delay is the length of an output pulse for a given signal at Increase input to comparator 53, the increase assuming a certain Frequency for the generator 48 lasts a fixed line. Even for a zero signal at the input to the Comparator 53 thus emerges -. 'In the output pulse certain length. Since in practice almost always a Minaesi pulse length is required in an arrangement, the provision of the delay enables the use of the matrix over a smaller range of pulse times, so that the resolution of the matrix \ is improved.

Referring to the rest of the circuit, the two operational quantities that are used to to regulate the length of the output pulse. Converters 22 and 23, the alternating signals with one frequency generate the \ <> m value of the operating variable, the two signals to gate circuits 71 and 72 ! 'which are guided by a signal from a ! iK> nostabiien circuit 24 for a certain period of time opened, with the oil opening eggs inonostable circuit 24 is controlled by the output from the comparator 53 via a line 25, so that with each passing of a signal to the counter 54 through the comparator 53 the monostable circuit 24 is caused to take effect for a certain period of time. If the gates 71 and 72 are open, the alternating signals are two counters 73 and 74 fed, each of which simultaneously with the monostable circuit 24 via lines 26 and 27 is evacuated. The counters 73 and 74 are with further counters 75 b / w. 114 connected. There is one such Arrangement provided that each time a counter 73, 74 has been cleared, it sends a signal to the counter 75 or 114 leads. Since the gate circuit 71 and 72 one are kept open for a certain period of time, the displays on the counter pairs 73, 75 and 74, arise, determined by the frequencies of the signals, which are controlled by the operating variables, wherein the most significant numbers of these indications are stored in counters 75 and 114, respectively, by the Decoders 13 and 14 operate to place signals on lines 11 and 12 as above has been described.

In order to obtain a more precise indication of the required imoule length, it is advisable to apply a relatively small signal to the signals applied to lines 11 and 12 which changes in size in a cyclical manner. The reason for this is that the input to matrix 77 is digital so that if, for example, line 116 is energized, the actual analog value ^{1 of} the operating quantity may be such that line Mb is energized. but the line Mn is just before the excitation. This possibility is taken into account by applying the small signal to the input to the matrix 77. The kind

and one way of doing this is to use counters 86 and 87 associated with counters 73 and 74, respectively, with counters 86 and 87 storing digital numbers from T through 16. These numbers are added to the numbers entered in counters 73 and 74 , then counters 75 and 114 when gates 71 and 72 are open. Whenever the comparator 53 produces an output and resets the counters 73 and 74, the counters 86 and 87 are incremented through the lines 31 and 32 to thereby increase the number which the counters 73 and 74 are counted got to. Counters 86 and 87 are cross-coupled and such an arrangement is provided that comparator 53 samples the output of matrix 77 16 times so that counter 54 needs 16 inputs before bistable circuit 46 is triggered.

It will be understood that the 16 tests take place very quickly and it is assumed in the description that neither one nor the other operating value changes during the short line. However, if the farm size changes, don't do anything because the arrangement will still produce a mean output that is more accurate. than if the counters 86 and 87 are omitted. However, it should be understood that the invention is not limited to the case. in which the operational quantities applied to matrix 77 vary, and the number of times in each cycle that a change occurs. is equal to the number of signals. which the counter 54 must receive before it triggers the bistable circuit 46. The invention can be used, for example, in an arrangement in which there is no change in the signals applied to the matrix 77. apart from normal changes in the operational quantities themselves. In this case, the number of counts that must be performed by the counter 54 can be determined according to the particular application of the system.

It has been assumed above that the generator 48 has a constant frequency. However, means shown at 35 are provided for changing the frequency of the generator 48 in accordance with one or more of the operating parameters related to the process, such that the delay time before a function of the TC circuit 51 is increased and a longer or shorter output pulse for F i g receives a specific input pulse to the comparator 53. 2 shows an exemplary embodiment for the generator 48 in which the frequency is set in accordance with three different operating variables. According to FIG. 2, a positive and a negative energy line 81, 82 are provided, which are connected to the vehicle battery 83 and are placed between the three resistors 84, 85 and 86. A slide 87 is movable via the resistor 85, which is connected to the control electrode of a thyristor 88, the anode of which is connected to the line 81 and the cathode of which is connected to an output terminal 89 which is the input to the gate circuit 47 in Fi g. 1 delivers. The anode-cathodes of the thyristor are connected through a capacitor, and the terminal 89 is connected to the line 82 via a series circuit. This series connection includes the collector-emission electrode path of a transistor 91. Furthermore, a resistor 92 and a thermistor 93. The lines 81 and 82 are also connected by a series circuit which includes a thermistor 94 and resistors 95 and%, the Connection between the resistors 95 and 96 is connected to the control electrode of the transistor 91 and a resistor 97 is connected in parallel to the thermistor 94.

The slide 87 is moved by means which are responsive to one of the three operating variables, so that the Position d: s slide 87 on the farm size depends. The other two operating quantities are used to heat the thermistors 93 and 94, see above that the thermistors assume resistances, which depend in each case on the operating parameters.

By disregarding the three operational quantities for the moment, the circuit works as follows. Starting with the thyristor 88 and off

ίο discharged; m capacitor 90 is the voltage on Terminal 89 essentially equal to the voltage of the Line 81. The transistor 91 and its associated parts charge the capacitor 90 at a constant rate, provided that the thermistors 93 and 94 are fixed in value. The control electrode of the thyristor 88 is held at constant tension, assuming that the slide 87 does not move, and as capacitor 90 charges, the voltage at terminal 89 decreases until a point is reached.

at your the control electrode of the thyristor is sufficient positive / around terminal 89 is opposite. to turn on thyristor 88, and discharge at that point the capacitor 90. The current flowing through the transistor 91 is below the holding current of the Thyristor 88. and therefore the thyristor 88 turns on. and the voltage at terminal 89 rises to Line 81 voltage. The cycle then repeats. Since the capacitor 90 with constant rale is loaded, the output of the circuit has a constant frequency. It goes without saying that the parts are chosen so that the transistor 91 is not saturates, otherwise the charge rate of the capacitor 90 is not constant.

If the operating quantity that controls the thermistor 93 changes and the other two operating quantities remain fixed, the collector emission electrode current of the transistor 91 changes due to the change in the value of the thermistor 93 and the charge rate of the capacitor 90 changes to thereby change the Beiriebsfre frequency of the circuit to change. Accordingly, when the operational quantity that controls the thermistor 94 changes, the control electrode current of the transistor changes; 91, and again the capacitor 90 is charged at a different rate so that the frequency changes. In both cases, the thyristor 88 still turns off, as explained above. When the operating size changes that controls the slide 87, the slide 87 moves and changes the control electrode voltage of the thyristor 88. In this case, it changes the value to which the capacitor 90 must be charged. to turn on the thyristor 88, and consequently the frequency is changed again.

For this purpose 2 sheets of drawings

Claims (3)

Patent claims: 1. Process control device for several main operating parameters and at least one secondary operating parameter, consisting of operating parameters and a memory for the converted Main operating parameters, the digital values corresponding to the main operating parameters a digital register for controlling an output signal controlling the process, thereby characterized in that a pulse generator controlled in frequency as a function of one or more secondary operating parameters (48) is provided, which after generating the output signal pulses to a logic (47, 49, 51) supplies which these pulses after a predetermined delay time for interrogating the digital register (77, 53), which, depending on the memory content, determines the length of a control pulse for the logic (47,49,51) determined, forwards. 2. Process control device according to claim 1, characterized in that the logic (47, 49, 51) has a counter (49), the input of which has a feedback AND link (47) with the Pulse generator (48) and with the output of an output signal delivering from the digital register (53) is connected to the control pulses triggered bistable circuit (46). 3. Process control device according to claim 1 or 2, characterized in that the pulse generator (48) a capacitor (90) which is charged by a transistor (91) whose control electrode current by a first secondary operating parameter and its collector current at a certain one Control electrode current can be determined by a second secondary operating parameter, and a thyristor (88) include its cathode voltage due to the charge on capacitor (90) and its Control electrode voltage can be determined by a third secondary operating parameter, the Charging of the capacitor (90) via the transistor (91) by switching on the capacitor (90) discharging thyristor (88) is terminated.