DE1673519C3 - Circuit arrangement for temperature control of thermostats heated with direct current - Google Patents

Description

The invention relates to a circuit arrangement for regulating the temperature of those heated with direct current Thermostats, using a bistable toggle switch that has one input on one The voltage divider is dimensioned so that at the setpoint temperature the directly coupled with this Trigger stage is live and in which at least one resistor is a temperature-dependent resistor is, which is arranged inside or on the heating jacket of the thermostat housing and that parallel to Voltage divider is a stabilization element and the flip-flop on the output side via a Diucie is connected to an electronic switch, the switching path of which is connected upstream of the thermostat winding is.

Particularly high requirements are placed on the Consensus of the carrier frequencies in carrier frequency systems placed. Often all of the carrier frequencies present in a system start from one base frequency derived, which in turn is generated by means of a basic generator. It must therefore be special Attention should be paid to the frequency constants of the respective basic generator. Therefore be Such basic generators are provided with a thermostat, which ensures that the ambient temperature of the basic generator maintains its constant value regardless of the outside temperature. For this, however, it is necessary to provide a regulation for the thermostat.

With conventional controls, quartz thermostats are used uses which mercury contact thermometer or bimetal switch as a temperature sensor and where relays are used as switching amplifiers. It leaves sirh bet such Arrangements do not avoid that a certain susceptibility to failure, especially seen over a long period of time, occurs.

US Pat. No. 3,028,473 is already a circuit arrangement for temperature control of mi! DC heated thermostats known, in which a bistable multivibrator with a transistor is controlled via a voltage divider, which is dimensioned in such a way that at the setpoint temperature the flip-flop that is directly coupled to it is energized and in which at least one resistor is a temperature-dependent resistor that is inside or is arranged on the heating jacket of the theimostat housing, in which also the output-side flip-flop is connected to an electronic switch via a Zener diode, and the switching path of the electronic switch is arranged in series with the thermostat winding.

This"; However, the arrangement has significant disadvantages. One of the disadvantages is that the thermostat windings are split ^! nd and that part of these windings is in the collector circuit of the transistor and another part in the emitter circuit of the transistor. This creates a sliding current negative feedback through the partial resistance of the thermostat winding, so that the flip-flop with the transistor only responds at higher input voltages.

Another disadvantage is that the input voltage is not stabilized, so that the tipping point cannot be determined exactly. The flip-flop circuit in the known arrangement exists from a switching transistor with feedback. The switching behavior of such a bistable multivibrator is however, its steepness is significantly lower than that of a two-stage transistor multivibrator.

Another similar temperature control circuit is known from US Pat. No. 3,114,025, which with has similar disadvantages.

The object of the present invention is therefore to provide a circuit arrangement for temperature control of thermostats heated with direct current, through which an improvement over the aforementioned control arrangements is achieved.

To solve this problem, the circuit arrangement for temperature control of with direct current heated thermostat designed so that two Zener diodes for voltage stabilization in parallel are connected to the voltage divider and with

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This form a bridge circuit, since the bistable Multivibrator consists of a two-stage multivibrator, the second input terminal of which with the connection point of the two Zener diodes is connected, and that the flip-flops with the electronic The diode connecting the switches is a zener diode.

These measures result in an extremely reliable and always reliable one Temperature control circuit for thermostats,

Compared to the arrangement according to the USA patent specification 3 028473 there is the advantage that with a much lower sensitivity of the Circuit a much higher stability with regard to the voltage at the input and thus the shift advantageous, if conventional control procedures apply in facilities already in operation the control circuit according to the invention can be replaced should, since in this case generally only ^ in limited Space is available.

No element protection is sought for the features of the subclaims.

On the basis of FIG. 1 and 2 the invention is explained in more detail. It shows

Fig. I a control circuit with a transistor as an electronic switch,

F i g. 2 a control circuit with a power gate as an electronic switch,

F i g. 3 a control circuit in which the second stage

the threshold value is reached. The invention of the toggle switch and the thermostat pulsate with it

d Glihng are operated

proper arrangement is therefore much better than the arrangement in its overall switching behavior according to the aforementioned USA patent.

Compared to the known arrangement according to US Pat. No. 3,114,025, the present Subject of the application has the significant advantage that the bistable flip-flop on the input side between the connection point of the two the voltage divider forming ohmic resistances and the connection point of the two Zener diodes, which this Voltage dividers are connected in parallel, so that the bistable multivibrator is from a bridge circuit is controlled. As a result, the Zener diodes not only cause taxed switching through of the bistable multivibrator, but by the fact that the emitter compared to the ground line and the amount of a Zener diode are raised, also an extremely low dependence of the circuit on temperature fluctuations. This dependency is given to a large extent in the known circuit, because the emitter is connected directly to ground, which reduces the temperature dependence of the emitter-base threshold voltage goes directly to the circuit. Dadi-rch, that also the coupling the DC voltage can be operated.

The heating winding 12 of the thermostat in FIG. 1 is switched on and off via the power switching transistor 16 switched off. The transistor 15 serves as a preamplifier

ao ker. About the one used to steepen the switching Zener diode 10 is the transistor 15 from a trigger stage, formed from u \ _n transistors 3 and 4, controlled.

The base of transistors 3 and 4 is against the

The negative pole of the circuit due to the constant voltage the zener diode 5 biased. This reduces the temperature dependency of the trigger stage and their switching sensitivity increased. The zener diode 5 serves simultaneously with the in series

switched Zener diode 6 to stabilize the supply voltage the tilting stage.

The two resistors 1 and 2 form a voltage part ι, which is also connected to the constant voltage the series connection of both Zener diodes 5 and

6 is switched on. Let the voltage divider ratio be initially chosen so that the transistor 3 is conductive at the set temperature of the thermostat. The voltage divider resistor 1 should be a Htißleiter, which inside or on the heating jacket of the thermostat

the bistable multivibrator is attached to the electronic switches.

ter takes place via a Zener diode and also a Schmitt trigger as a multivibrator instead of a unijunction transistor is used, the switching effect is further improved.

In summary, it can therefore be stated that the switching quality of the entire arrangement both as far as the temperature dependence and the steepness of the switching are concerned, compared to this known circuit is significantly improved.

As is known per se, hot conductors and / or PTC thermistors can be used as the temperature-dependent resistor. A particularly high temperature constancy can be achieved with the simultaneous use of hot and cold Reach PTC thermistors.

Transistors can advantageously be used as electronic switches. For larger thermostat heating capacities it is advantageous to use transistors instead of controlled electronic switches Use silicon semiconductor rectifiers. The steepness of the control of the circuit can be determined with the help of an amplifier, which is connected upstream of the control electrode of the electronic switch, increase even further.

If pulsating direct current is used to supply the second Kippstute with direct current, then it can be especially the one required for rectification Significantly reduce the storage capacitor, thereby reducing the dimensions of the entire assembly can be reduced in size. This is mainly because the transistor 3 is conductive 4 is blocked, via the collector load resistance of the transistor 4 and the Zener diode 10, the Transistor switching arrangement with transistors 15

and 16 switched through and the thermostat heating resistor flowed through by the heating current. As a result of the heating, the value of the thermistor 1 is reduced. The transistor 3 is blocked and the transistor 4 becomes conductive. The breakdown voltage of the Zener

diode 10 is not reached. The activation of the transistors 15 and 16 is interrupted. After a the process is repeated again after a certain reduction in the thermostat temperature.

You can use the resistance 1 as a con-

Form a constant resistance and use it as a resistance 2 use a ceramic PTC thermistor, which in this case is used as a temperature sensor. the PTC thermistor has the advantage that ζ. B. at + 60 ° C its temperature coefficient is six times greater than that of one

Thernewids is. This means that the thermostat temperature is much more constant.

You can improve the constancy even more if you use the Thernewid 1 as well as the PTC thermistor 2 used as temperature sensors at the same time. Because temperature changes are relatively slow success), it is smaller for quick switching of the toggle switch while at the same time desired Hysteresis useful, the capacitors 8 and

to be inserted into the circuit in a suitable size.

Taking into account the possible retrofitting of devices in operation, it is advisable to feed the arrangement from a 20 V tube heating voltage for the frames of the message transmission technology via the bridge rectifier 14. No screening is generally required for the transistor switching arrangements 15 and 16. In the present example, its operating voltage is approximately 0.9 (J ,,, (V _t " = 20 volts).

Sufficient sieving is required for the first stage of the multivibrator, the second stage, on the other hand, can be operated with pulsating direct current. The current requirement of the flip-flop is only a few milliamperes. The rectified voltage is fed to the charging capacitor 7 via the decoupling diode 13 and is then approximately 1.4 ½ ». This is advantageous because it allows the series resistor for the Zener diodes 5 and 6 to be selected to be larger and, as a result, a better voltage stabilization is obtained.

For larger thermostat heating capacities, it can be an advantage instead of transistor switchgear with the transistors 15 and 16 in FIG. 1, a circuit with a silicon current gate II according to FIG. 2 to use. A rectification would be 14 not necessarily required.

It is also possible to switch two antiparallel Use power torc. In this case, however, the control circuit becomes much more complicated.

ίο In Fi g. 3 shows a circuit arrangement at which uses a transistor as an electronic switch. The / wide stage of the toggle switch is here, just like the thermostat, is fed with a pulsating DC voltage. The first stage will

»5 is supplied with a filtered DC voltage. The names in the arrangement correspond to the designations in FIGS. 1 and 2.

Radio interference suppression agents that may be required to avoid this cracks in the TF channels

»O Switching the thermostats is for the sake of clarity ir the circuits are omitted.

1 sheet of drawings

Claims (6)

Patent claims: 1. Circuit arrangement 2 for temperature control of thermostats pickled with direct current, using a bistable flip-flop which has one input at one The voltage divider is dimensioned so that at the setpoint temperature the directly coupled with this The flip-flop is energized and where * o at least one resistance is a temperature-dependent one Resistance is arranged inside or on the heating jacket of the thermostat housing and that parallel to the voltage divider is a stabilizing element and in which the flip-flop connected on the output side via a diode to an electronic switch, the switching path of which the thermostat winding is connected upstream, characterized in that two Zener diodes (6.5)? For voltage stabilization in parallel ao to the voltage divider (1, 2) are connected and form a bridge circuit with this that the bistable multivibrator consists of a two-stage multivibrator (3, 4), the second input terminal of which with the connection point of the two 2-enerdioden (6,5) is connected, and that the Flip-flops (3, 4) with the electronic switch (16) connecting the diode (10) is a Zener diode. 2. Circuit arrangement according to claim 1, characterized in that as a temperature-dependent Resistors hot and / or PTC thermistors are used. 3. scarf, arrangement according to claim 1 or 2, characterized in that. A transistor (16) is used as the electronic switch. 4. Circuit arrangement according to claim 1 or 2, characterized in that as electronic SchalUr a controlled semiconductor rectifier (11) is used. 5. Circuit arrangement according to one of the preceding claims, characterized in that that the control electrode of the electronic switch has a preamplifier (15) Zener diode (10) is connected. 6. Circuit arrangement according to one of the preceding claims, characterized in that that the direct current supply of the second flip-flop (4) takes place with pulsating direct current.