DE3024945C2 - Changeover switch for a controller - Google Patents

Description

The present invention relates to a changeover switch for a controller according to the preambles of FIG independent claims.

Such a switch is known from DE-OS 23 35 372. This is about a control or regulating circuit to connect at least one preferably adjustable setpoint adjuster. The setpoint adjuster are designed as potentiometers in series with two Switching paths of two transistors are so that the Setpoint adjuster with its two connections separated from the supply voltage or connected to it can be. It is not intended to use external setpoint adjusters or actual value transmitters. an evaluation scarf

switch on.

The present invention is therefore based on the object, in a regulator of the type mentioned at the outset a simple switchover of the connected target value resistor to an additional target value or To enable actual value resistance without being caused by special switching processes, except for the inrr Utclbare Connect the feed lines to the resistor in which the device must be tampered with.

The solution to this problem succeeds through the characteristic Features of claim 1 and claim 2. The particular advantage of this measure Takes place in that an open sensor connection with exclusive Control of the setpoint or actual value through the internal resistor is avoided, as this is open Sensor connection the measuring bridge normally detuned so much that the amplifier of the evaluation circuit is overridden and thus inoperable. Incorrect operation is due to the lack of a special one Switching device excluded.

Further refinements of the invention can be seen from the following description, which shows an exemplary embodiment the invention explained in more detail with reference to Figures one to three of the drawing

Through the invention it is possible, for example the Charging setpoint of a night storage heater not only from the central setpoint of the outside temperature, but can also be acted upon by an individual setpoint value, for example by a parallel shift.

It is also possible that the discharge setpoint of a night storage heater is not only based on the central setpoint of the room temperature, but also from an individual one The setpoint is acted upon, for example by a sun sensor with room influence, which acts as a window sensor is trained. In the field of heating technology it would be conceivable that a supply temperature control additionally from a setpoint / icr outside temperature instead of room temperature. Show it! Fi g. 1 shows a basic circuit diagram of the invention,

F i g. 2 a variant of the basic circuit diagram and

F i g. 3 shows a more precise circuit for a regulator, utilizing the principles according to FIGS. 1 and 2.

In all of the figures, the same reference symbols mean in each case the same details.

In Fig. 1, a controller is shown in part. Within a controller housing 1, which has two terminals 2 and 3 for lines 4 and 5 leading to the outside, to which a potentiometer 7 equipped with a slider 6 is connected, a bridge circuit 8 is provided, of which only one bridge element 9 is visible is connected to the operating voltage plus and minus LJB . The bridge branch 9 is divided into two bridge branches 10 and 11, of which the bridge branch 11 consists of a fixed-value resistor 12, while the bridge branch 10 consists of the series connection of a potentiometer 14 provided with a wiper 13, a fixed-value resistor 15 and a transistor Ib of the PNP type with its collector Emiucrsirccke consists. A diagonal bridge 17 in the form of a line provided with a resistor 18 extends from the connection point of the two bridges 10 and 11.

A further branch 19, which starts from minus UB via a resistor 20 and is connected to plus LJB via the collector F.mitterstreckc of a second transistor 21, is parallel to the bridge circuit 9. Both transistors are of the same conductivity type. The collector of the transistor 21 or the AsI 19 are connected to the base of the transistor via a resistor 22

stors 16 connected. The base of the second transistor 21 is connected to the terminal 3 via a line 23 into which a Resistor 24 is inserted, connected, the series circuit from Emilter base line of the transistor 21 and dsm resistor 24 is bridged by means of a line 25 into which a fixed-value resistor 26 is inserted Terminal 2 is via a line 27 to the connection point 28 of the bridge branches 10 and 11 respectively connected to the bridge diagonal 17.

The in F i g. 1 circuit shown has the following function: It is assumed that the Bridge branch 9 is another not shown bridge usl is connected in parallel, which has a fixed-value resistor and a sensor resistor, the sensor resistor be controlled, for example, by a pressure transducer, see that a voltage signal is present in this bridge branch is generated, which is variable with the pressure of a pneumatic encoder and thus the actual value branch of the Controller represents. Branch 9 represents the target value branch. Provided that the clergymen 2 and 3 are not coated, i.e. the potentiometer 7 is missing, the transistor 21 is blocked, the transistor 16 conductive through the coupling via the resistor 22. The resistance of transistor 16 is practical Zero compared to the value of the resistors 14, 15 and 12. This is practically only for the potential at point 28 the set resistance on the wiper 13 of the potentiometer 14 is decisive, so that by adjusting the Grinder 13 the target value for the pressure regulator is specified can be. The deviation between the actual and the target value is foaled in the course of the bridge diagonal 17 and given to an evaluation circuit and from there to an actuator that controls the pressure in the Regelstrekkc either increased or decreased, depending on the function of the controller.

If a remote control is to take place so that the internal setpoint encoder in the form of the potentiometer 14 is to be switched ineffective, the potentiometer shown is connected to terminals 2 and 3. Thus, a current can flow between plus and minus UB via the line 25, the resistor 26, the potentiometer 7 and the resistor 12, which brings the transistor 21 into the conductive state. That means blocking the T-anisistor 16, so that the desired value branch 10 is practically separated from plus UB . The potential at point 28 is therefore determined exclusively by the setting of the wiper 6 on the potentiometer 7.

I3ci the exemplary embodiment according to FIG compared to the) embodiment according to FIG. 1 not about an internal / external soil value switch, but rather an internal / external actual value switchover for a Regulator. The bridge 8 is present in the controller in an analog manner, and the target value encoder potentiometer 14 is an actual Wcrlgcbcr provided in the form of a sensor resistor 30, which, for example, the flow line of a Sammcl-Hci / .ungsanlagc assigned. This sensor resistor is an NTC resistor. Lead the lines 4 and 5 from terminals 2 and 3 to an external 1st value transmitter 31, which comes from the parallel connection Another NTC sensor resistor 32 with a fixed value resistor 33 is made.

The function of the exemplary embodiment according to FIG. 2 is as follows: If the terminals 2 and 3 are not trained, then due to the fact that the exemplary embodiment according to FIG. described mode of operation only the Isl value transmitter resistor 30 for the evaluation of the bridge signal in the bridge diagonal 17 is decisive. The actual value si _fa . '. Il from the bridge branch 9 is compared with a target value signal in a bridge branch (not shown) in the bridge diagonal 17 and fed to an actuator, for example the gas solenoid valve of a boiler, to set the flow temperature according to the size and type of Increase or decrease control deviation.

Should only the flow temperature at another point than are measured directly in the boiler, for example, at this point, for example the pre-flow, the external actual value transmitter 31 is connected so that the NTC resistor 32 directly determines the flow temperature, for example in the heating circuit. Thus terminals 2 and 3 are as indicated wired. The fixed resistor 33 is only used for the conductance linearization. The parallel connection of resistors 26 and 24 is also part of the linearization network. As a result of the parallel connection of resistors 32 and 33 to. the terminals 2 and 3 becomes the transistor 21, which was blocked before «· * -.

conductive and the transistor 16 blocked, which was previously conductive. The bridge branch 10 is thus high-resistance, so that the external 1st value transmitter 30 is no longer functional and the system deviation is only due to the NTC-Wide, 32 stood in connection with the target value branch the bridge is generated. If the external actual value transmitter 31 is detached from terminals 2 and 3 the internal actual value transmitter 30 becomes effective again for the controller.

In the embodiment according to FIG. 3 is a heating controller with two internal and external target value transmitters that are operated with a day / night switchover. Here is the bridge 8 with further details are shown.

In the course of this bridge 8, three actual value branches 40, 41 and 42 are switched from plus UB to minus UB , each of which has an actual value transmitter resistor 43, 44 and 45, each with a fixed value resistor 46, 47 and 48 are connected in series. The connection points between the sensor and the fixed-value resistor are each wired with a decoupling resistor 49 and 50 and 51, so that the respectively variable voltage drop at the sensor resistor of the respective branch can be given to an evaluation circuit not shown further. (The resistors 49, 50 and 51 determine the influence of the individual sensors.)

The target value bridge branch 9 is switched differently. From UB , the emitter-collector path of a transistor 52 or 53 leads to a fixed-value resistor 54 or 55 and to a nominal value transmitter potentiometer 56 or 57 with sliders 58 and 59, respectively. The slider taps or the end points of both potentiometers lead to connections 60 or Gl of a changeover contact 62 which is controlled by a synchronous motor 63. The changeover contact 62 is connected to the point 28 or the bridge branch 11 and the fixed-value resistor 12 via a line.
The bases of the two transistors 52 and 53 are connected to the collector of transistor 21 and line 19 via fixed resistors 64 and € 5, respectively. On one side of the line 4, base points and sliders 6fe and 67 of two potentiometers 68 and 69, respectively, are connected, which represent external setpoint value transmitters. The potentiometer 68 is connected to a terminal 70, the potentiometer 69 to a terminal 71. The effect of the terminals 70 and 71 corresponds to the terminal 2 of the F i ε. 1.

A line 72 leads from the terminal block 70 to the base of the potentiometer 57 or to the latter Wiper, from terminal 71 a line 73 to the base or wiper of the potentiometer 56. The synchronous motor 63 is a clock motor that switches the switch 62 to from about 7:00 a.m. to 10:00 p.m. Contact 60 sets in order to operate a connected heating system with a first target value. To the other time, the switch 62 is on the contact 61, to the heating system at night with a Night setback, i.e. a different setpoint, to operate. The actual value sensor resistances 43, 44 and 45 sense, for example, the flow temperature for the heating circuit, the outside temperature and the room temperature away. These actual values are above the decoupling resistors 49.50 and 51, which together with the resistor

ter shown atiswerteschaltung. In the position of the contact 62 shown, the potentiometer 69 is effective for the bridge diagonal, with lines 4 and 74 or 75 connected to the terminals 3, 70 and 71, due to the already described effect of the external setpoint value transmitter desired target value can be set. Due to the already described mode of operation of the transistors 52 and 21, the internal setpoint value corresponding to the position of the wiper 58 on the potentiometer 56 has no effect. If the motor 63 switches the changeover switch 62 to the contact 61 after 10 p.m., the external target value transmitter becomes effective according to the position of the wiper 66 on the potentiometer 68 and supplies the controller with a night target value. By removing the lines 4, 74 and 75 from the terminals 3, 70 and 71, the internal setpoint value transmitter becomes effective again, namely the one that is currently connected to the bridge diagonal via the changeover switch 62.

For this purpose 3 sheets of drawings
40

Claims (2)

Patent claims: 1. Changeover switch for a controller with a DC operating voltage and a bridge circuit, which has an actual value branch and two parallel-connected target value branches, one of which is active in each case and where the actual and setpoint generators consist of resistors and are connected to two opposite connection points of the branches of an evaluation circuit are, characterized in that the setpoint generator (14) in the first setpoint branch (10) is in series with the switching path of a first electronic switch (16) and that the second setpoint branch (4,5) consists of a second electronic switch (21) another set value transmitter (6), wherein the switching trek the second electronic switch (21) parallel ZAM first setpoint branch (10) and the control electrode of the first electronic switch (16) connected to a terminal of the switching path of the second electronic switch (21) is and that when connecting the further setpoint device between hen the control electrode and one connection of the Schah section of the second electronic switch, the setpoint generator (14) of the first setpoint indicator (10) is switched off. 2. Changeover switch for a controller with a DC operating voltage and a bridge circuit, the one Has actual value branch and two parallel-connected setpoint branches, one of each active from denci is, and where the actual and setpoint generator consist of resistors and two fe., - opposite Connection points of the branches of an evaluation circuit are connected, characterized in that that in the first actual value branch (10) the actual value transmitter (30) in series with the switching path of a first electronic switch (16) and that the second actual value branch (4, 5, 23) consists of a second electronic switch (21) with a further actual value transmitter (31), the switching path of the second electronic switch (21) is arranged parallel to the first actual value branch (10) and the control electrode of the first electronic switch (16) with a connection of the switching path of the second electronic switch (21) is connected and that when connecting the further actual value transmitter between the control electrode and one connection of the switching path of the second electronic switch (21) the actual value transmitter (30) of the first actual value branch (10) is switched off.