DE2322694C3 - Circuit for generating a time-variable comparison voltage as a sliding setpoint in electronic temperature controllers - Google Patents

Description

The invention relates to a sound system for generating a time-varying comparison voltage as a sliding setpoint in electronic temperature controllers for cooling or heating processes using a transducer for the actual temperature, preferably a thermocouple, whose voltage is compared with the reference voltage.

The heating up or cooling down of ovens, gaps in the factory, etc. is usually not carried out in practice linear heating or cooling rates, but usually follows an exponential one Time-temperature law But it is also common to use only certain temperature ranges with a linear Aufhciz-Uml Go through cooling rate and heating or cooling in the neighboring Temperature ranges according to an exponential time-temperature law.

While the linear time-temperature curve z. H. is sufficiently defined by specifying ° C min, the exponential time-temperature curve can be described by specifying the time constant τ. The value of the time constant c τ in seconds means that after this time τ has elapsed, the output value of the temperature / ur time i "in the concrete case has decreased by the factor (), 3dH. After a period of 2 r has elapsed, the initial value of the temperature / ur time / "has decreased by the factor (), 3nK ² , etc.

During the regulation of heating oiler cooling processes with a linear cycle of temperature and temperature, it is usually carried out relatively easily in practice prepares the regulation of such processes, an exponential law of time and temperature should follow, usually considerable difficulties.

The regulation of heating or cooling processes generally takes place in the form that, for. H. the factory leakage measured with a thermocouple or the actual furnace temperature is continuously compared with the previous temperature setpoint and the differences

»O rence between actual value and setpoint to a minimum in each case is regulated.

The Temperaturistwerl is usually through Measurement carried out with a thermocouple or a comparable transducer,

• 5 where the measured variable is an electrical voltage in general of the order of mV ai'.fälll. Accordingly, an electrical voltage source is also used as a setpoint generator, which is used for comparison supplies a voltage of the same order of magnitude with the actual value. This voltage is usually regulated by adjusting a controllable voltage divider (potentiometer) in the nominal voltage circuit. The voltage provided by the setpoint generator is then fed to the actual controller, which continuously compares the actual value / ί with the setpoint and when there are differences, the heating output of the furnace controls in the direction that the difference is a Minimum reached.

The regulation of heating or cooling

3 «went with a linear temperature curve in the generally carried out in such a way that the SoII-wcrlpotentiomcter your desired time-temperature curve with the help of a simple electromechanical drive z. B. in the form of a gear motor with gradual speed adjustment is adjusted.

In contrast, the regulation of heating and cooling processes requires an exponential Time-Temperalur-Geselz should follow, for

1 "the adjustment of the setpoint device a comparatively much greater effort, such as H. special functional gears or complicated camshafts.

There is a control system, in particular for controlling temperatures, in which a Ramp generalor is a preferably linearly variable setpoint for a temperature controller will. The control system just mentioned is relatively complicated and, moreover, as already mentioned above was stated - linearly variable setpoints for cooling or heating processes often disadvantageous.

The invention is based on the object of avoiding the above-mentioned disadvantages and a relatively very simple device for the particularly advantageous regulation of cooling oiler To create heating processes.

According to the invention, this is achieved by means of a circuit of the type mentioned at the beginning, tlali / ur Generation of an exponentially running comparison voltage to an RC element via a switch a DC voltage is connected and that a buffer amplifier is connected downstream of the RC element, whose input resistance to the wilei-

<> 5 said the RC link is very angry and preferably at least ten times the specified allowance / t Resistance is and whose Atisgangsseitc is connected to the control loop.

Because during one time the temperature curve is hot exponential Heating up or cooling down due to the heat capacity of the system and the heat exchangers -Discharge to or from the nestimmi system depends the time-voltage curve when charging or discharging an electrical capacitor from its capacity and on the size of the resistor through which the charge or discharge current flows. Accordingly can be the time constant of a charging or discharging process according to the formula

T = RC equation (1)

can be calculated, where r is the time constant in seconds, R is the discharge resistance in megohms and C is the capacitance of the capacitor in microfarads. Compared with the known devices for regulating cooling and heating processes, the circuit according to the invention offers the advantage that it allows such processes to be controlled automatically in a more precise and relatively simple manner.

In the following the invention is explained in an exemplary embodiment, which is illustrated by the drawing in schematic representation is illustrated. Fig. I shows in a coordinate system the means the circuit shown in Fig. 2 achieved exponcnticllen Time-temperature curve through a solid curve (and comparatively that on earlier Position mentioned linear time-temperature curve through a dash-dotted straight line), with the abscissa represents the time axis and the ordinate represents the temperature, thermal voltage, etc. the 2 shows a possible embodiment of the circuit according to the invention.

The voltage required to charge the RC element 3 is supplied to the RC element via a switch 2 supplied from a DC voltage source c 1. With the switch the charging process can be initiated and be terminated. Charging corresponds to heating up, discharging corresponds to cooling down. The desk 2 can basically be used in two operating modes.

Operating mode I:

With this type of function, the loading process is initiated manually or via electrical auxiliary circuit relays by closing switch 2 or the discharging process by opening switch 2. With this function of switch 2 ew's, the time constant of the RC-Giiedcs corresponds to the product R times C.

Operating mode 2:

The switch 2 works in such a way that after the completion of the charging process, the discharging process of the RC element is initiated first; During the discharging process of the RC element, however, the capacitor is recharged with a specific, adjustable amount of charge by means of brief pulses via switch 2, the amount of charge being smaller than the amount of discharge, as otherwise no discharge can take place. In this way, the discharge process can be lengthened or slowed down as desired. The extent of the lengthening can be determined by the ratio between the switch-on times and ilen switch-off times, the so-called duty cycle or the recharge amount. In order to achieve a quasi-continuous discharge process of the RC element, the impulse-like recharging of the capacitor should take place at any frequency, but preferably with more than K) Hz, whereby the duty cycle should remain constant during the entire discharge process of the RC element. For example, a duty cycle of 1: 1 (50 % switched on or 50 % switched off - at least 10 χ per second) results in a doubling of the time constant r during the charging process. It is also essential that in this way not only the discharging but also the charging process of the AC element slows down

" leaves.

In order to regulate also very slow process of heating and Abkiihlungsvorgänge exactly in the manner described, it is advantageous if the Zeilk ^r> nstante the RC element 3 is as large as possible. To

* 5 equation (1) this means that for such a RC element high resistances and capacitors with large capacitance should be used.

If such an RC element is now mi! connected to the actual control loop 6, so must be guaranteed be that the internal resistance of the control circuit 6 is much greater than the resistance of the RC element 3, since in the opposite case the capacitor ties the RC element essentially not exclusively via its resistance, but more or less also via the internal resistance of the control loop which would lead to a change in the time constant of the RC element and thus to a The characteristic of the setpoint generator changes.

To eliminate this source of error, it is provided that a buffer amplifier 4 with a very high resistance of the input circuit (ie with a very high input resistance or with a very high input impedance) is connected between the RC element 3 and the control circuit 6. This amplifier 4 is to be designed so that its input resistance is greater than the discharge resistance of the RC element 3 used, preferably by at least ten times.
The voltage output by the RC-Glicd 3 and the nachgcschalleten buffer amplifier 4 is of the order of a few volts. In order to be able to carry out a setpoint-actual value comparison in the control circuit 6, the output voltage of the buffer amplifier 4 must be adapted to the order of magnitude of the measurement voltage emitted by the temperature sensor 7 (thermocouple, resistance thermometer). For this purpose, a suitable voltage divider 5 is connected between the buffer amplifier 4 and the control circuits.

1 sheet of drawings

Claims (3)

Patent claims: 1. Circuit for generating a time-varying Comparison voltage as a sliding setpoint in electronic temperature controllers for Cooling or heating processes using a transducer for the actual temperature, preferably a thermocouple, whose Voltage is compared with the comparison voltage, characterized in that for Generation of an exponentially running comparison voltage via an RC-Cilied (3) Switch (2) to a DC voltage nucleus (1) is connected and that the RC element (3) is followed by a buffer amplifier (4) whose Five-way resistance compared to the resistance of the RC element * (3) is very large and preferably is at least ten times the last stated willingness and its starting page is connected to the control circuit (6). 2. A circuit according to claim 1, characterized in that a voltage divider (5) is connected between the buffer amplifier (4) and the control circuit (6). 3. A circuit according to claim 1 or 2, characterized in that the capacitor of the RC-Gliedcs (3) by short-term impulses via the switch (2) with a certain adjustable Charge amount, which must be smaller than the discharge amount, can be recharged