DE1107773B - Electrical switching arrangement for triggering switching, control or regulating processes through several switching or measuring elements of the same type that take effect in any order - Google Patents

Description

Electrical switching arrangement for triggering switching, control or Control processes through several similar processes that take effect in any order Switching or measuring elements The invention relates to electrical switching arrangements, in which several switching functions of the same type that take effect in any order or measuring organs, in particular electrical contactors, by means of them switched here Auxiliary circuits trigger corresponding switching, control or regulation processes. the Auxiliary circuits should preferably be able to gradually connect and disconnect one or several power machines automatically depending on switching or measuring processes steer.

Such dependency circuits are often required. For example are electrically heated systems and rooms by gas, steam or hot water several heat sources from heated, depending on the in the individual parts of the systems or rooms prevailing, for example temperatures monitored by temperature sensors or depending on the connection and disconnection of other parts of the system and rooms must be switched off or amplified. Similar relationships may relate to the pressure conditions in pressure chambers, the liquid inlet and outlet in lines and channels, the concentration of chemical, monitored by measuring instruments Liquid lines, moisture or nitrogen enrichment in rooms and the like occur. In another example, the number and / or strength must be several The motor-driven fans serving to supply fresh air are matched to this which or how many are used to extract the stale air motor-driven fans are switched on. The case is similar when coordinating the drives of a plurality of feeding transport routes, in particular Conveyor belts on the drive or drives of one or more of the onward conveyance serving transport routes, in particular conveyor belts. Often here is the number the switching or measuring elements that trigger the switching, control or regulation processes, yes even several times greater than the number of dependent switching operations or Switching elements. The switching processes can consist of switching several motors on and off or consist of gradually changing the speed of a single motor. For example, when switching any three supply air fans on and off an exhaust fan can be switched on or out of operation respectively. a single Exhaust fan or its speed can be regulated up or down. As is known, this change in speed can be multiple in electric motors In the case of rotary motors, for example, by changing the pole accordingly wound motors.

A large number of dependency circuits are known. As long as it is in this case according to their order of switching operations that are clearly assigned to one another it is still possible, even if it is sometimes quite difficult, to do this To create dependencies corresponding control and interlocking circuits.

Should now, however, differ from the number of switching and measuring elements Number of switching, control or regulation processes regardless of the sequence of the When the switching and measuring elements become effective, it will be extraordinary difficult, possibly even practically impossible, all possible variations to create or incorporate a capturing dependency circuit.

Eliminate these difficulties and a very simple and easy one The aim of the invention is to create safe dependency switching anyway.

It consists in the fact that in the switching arrangement described above the various auxiliary circuits with regard to their voltage or current values in the Relation to the limit measured values (response values) of the associated measuring elements or graduated to the control services of the associated switching elements and under summation their voltage or. Current values with one of them in common, with possibly adjustable Control contacts provided measuring device are connected to the dependent wedge from the sum of the voltage or current values of the auxiliary circuits that are switched on triggers one or more control, switching or regulating processes.

A switching arrangement in which the voltage values of the auxiliary circuits are added, is designed according to a development of the invention so that the Auxiliary circuits in the form of transformers when the associated switching or measuring elements are operated Contain excited voltage sources that are connected to each other via the auxiliary contacts and are connected to the measuring device that they are independent of the order of their Switching on can be switched one after the other.

When applying the invention to contactor controls serve according to a Further development of the invention, the contactor coils as primary coils and excite in the Secondary coils located in the auxiliary circuits, which are each assigned by two to the contactors Pairs of normally closed contacts and normally open contacts are switched.

In contrast, when the invention is applied to mechanical switching or Measuring organs the voltage sources secondary windings of a common, a primary winding having transformer, each assigned by one of the switching or measuring elements Break contact and make contact can be switched.

Should now the current values of the auxiliary circuits instead of the voltage values are added, then the auxiliary circuits can be connected in parallel to a common power source connected and, in addition to the auxiliary contacts that switch them, the associated ones Have current value determining switching elements. This can be used as the current value determining switching elements are ohmic, inductive or capacitive resistances. When used on contactor controls, the control circuits are then appropriate as auxiliary circuits and their contactor coils as switching devices that determine the current value used.

In this case, according to the invention, there are two normally closed contacts for each contactor and two normally open contacts are assigned, of which the normally closed contacts are switched on the contactor coils are used, while the make contacts are used after switching on of the contactor coil circuits as auxiliary circuits. It can influenced by the sum of the voltage or current values of the auxiliary circuits, with Measuring device with control contacts directly or via intermediate relay contactors control that switch one or more electric motors on, off or over.

If the switching arrangement shown is used to control the Removal of liquid or gaseous media depending on the supply of the called media, then the arrangement is preferably made so that with Control contacts provided measuring relay on a controllable with respect to its speed DC, AC or three-phase motor, in particular a pole-changing three-phase motor, acts.

Some exemplary embodiments of the invention are given below of the drawing in connection with an arrangement in which a number of electrically driven conveying machines for the supply of any media, such as liquids, bulk solids and especially electric fans of the promotion of supply air and in which only one, in its speed gradually Changeable motor provided as a drive for a conveying machine serving for removal is. Here Fig.l shows a voltage-dependent control with transformer Partial voltages generated by the pull coils of the control switch, FIG. 2 a voltage dependent Control with partial voltages generated by an additional transformer, Fig. 3 a current-dependent control with taken from a common voltage source Partial currents, Fig. 4 a current-dependent control with through the current of the actuating coils Partial flows supplied by control switches and FIG. 5 shows a modified embodiment the control according to FIG. 4.

In the control arrangement according to FIG. 1, three electric motors 1 are used to drive three hoisting machines, e.g. B. supply air fans, the contactors 2 are equipped with a contactor coil 3, a secondary coil 4 and two alternately by a switching piece 5 bridged pairs 6, 7 of auxiliary contacts. The contactor coils 3 can each be connected to a control voltage source 9 and switched on by means of control switches 8. The secondary coils 4, which are energized individually by the contactor coils 3, can act on a control circuit 10 which contains the coil 11 of a contact relay 12. They are short-circuited in the rest position of the associated contactor 2 by the contact: 5 via the contact pair 6, while they are switched on by the same contact 5 via the contact pair 7 in the control circuit 10 when the contactor 2 is actuated. The upper contacts of the two contact pairs 6, 7 are electrically isolated from one another, whereas the lower contacts of these contact pairs are electrically connected to one another. The top contact of the contact pair 6 of the first contactor 2 and the bottom contact of the contact pair 7 of the last contactor 2 are connected to the control circuit 10. As a result of this circuit, the secondary coils 3 of the respective actuated contactors 2 switch themselves into the control circuit 10, regardless of the sequence of the contactor actuations, that they each send the voltage generated in it, for example 4 volts, and that these voltages, in turn add up to each other regardless of the position of the respective operated contactors. As a result, the coil 11 of the contact relay 12 is supplied with a higher voltage the more contactors are switched on, ie the more motors 1 are working.

The contact relay 12 has several pointer depending on the size the excitation of its coil 11 actuatable and possibly adjustable contacts, which influence an intermediate relay 14 via lines 13. This in turn switches the pull coils of three contactors 15, with the help of which a pole-changing motor 16 can be switched to the speeds corresponding to its pole pair numbers. As a result, this motor 16, which in the exemplary embodiment is used as the drive motor is intended for exhaust air, the higher the speed, the more motors 1 switched on, d. H. so the more supply air fans are put into operation. the The number of motors 1 can be increased as required. With appropriate dimensioning of the Secondary coils 4 of the contactors 2, the coil 11 of the contact relay 12 and setting the contacts of this relay can then switch the motor 16 of the power the respectively switched on motors or their fans or the like without further ado be adjusted.

As a rule, the motors 1, the conveying machines driven by them and the secondary coils 4 are dimensioned identically in order to obtain easily overlooked conditions in this way. It is possible, however, to achieve the desired voltage dependency of the control circuit 10 and thus of the circuit of the motor 16 by appropriately dimensioning the secondary coils 4 of their associated contactors 2 for different sizes and powers of the motors 1 and their conveying machines. It is also possible to use a controllable DC or three-phase motor instead of the pole-changing motor 16 and to control its speed in the usual way. Finally, in systems with a larger number of motors 1, several motors 16, for example one motor 16 for each three motors 1, can be provided and switched on and off by the intermediate relay 13 depending on the voltage.

2 shows a switching arrangement in which, for example, any three organs 17 dependent on changes in state, such as drives in the form of valve tappets, slide rods, etc., or measuring elements, in the form of temperature sensors, pressure capsules, etc., are provided with auxiliary switches 18. The switching levers of these auxiliary switches 18 interact with an upper contact 19 and a lower contact 20 each. Here, the upper contacts 19 are each except for that of the first auxiliary switch 18 connected to one end of a secondary coil 21 of a transformer 22, while the lower contacts 20 of the auxiliary switch 18 except for that of the last auxiliary switch 18, which is directly connected to the other end of the associated secondary coil 21 is connected, via the connection points of the auxiliary switches 18 are connected to the second ends of the associated secondary coils 21.

The connection point of the first auxiliary switch 18 and the lower contact 20 of the last auxiliary switch 18 are connected to the two ends of a control circuit 23 which, similar to the embodiment of FIG. The other switching connections of this relay are the same as in FIG. 1.

In the circuit in this embodiment, as in previously described embodiment of each adjusted organ 17 independently from its position in the control circuit 23 generates a partial voltage, and these voltages add up again regardless of the position of the activated organ.

In the exemplary embodiment according to FIG. 3, there are again three organs 17 which are dependent on changes in state of any kind and which are each equipped with an auxiliary switch 24. However, here the switching levers of the auxiliary switches, together with one switching contact 25 each, are connected in parallel to one another to a control circuit 27 fed by a control current source 26. This contains the current-dependent coil 28 of a contact relay 29 in this case, the further circuit of which corresponds to that of FIG.

There are ohmic resistors 30 in the branches of the auxiliary switches 24 switched on, also by inductive resistors 31 or capacitive resistors 32 can be replaced.

In this embodiment, the currents add up and it happens hence one that only depends on the number, but on the position of the displaced Organs 17 independent actuation of the contact relay 29.

In the embodiment of FIG. 4 is also a current-dependent Switching arrangement shown. This is the actuation circuit of the contactor coils used as a control circuit for the contact relay. Each engine 1 are as in Fig. 1 is assigned a contactor 2 with a contactor coil 3 and a control switch 8. The contactor coils 3 with the control switches 8 are parallel to one another on one of a power source 9 fed circuit 33 is connected, one of which is a supply line 34 is guided via the coil 28 of a contact relay 29. There is no need to explain that here, too, a dependent only on the number of operated contactors 2, but of whose position independent adjustment of the contact relay 29 must occur.

The circuit arrangement according to FIG. 5 corresponds in its essence to that according to Fig. 4. It differs from this only in that the actuating circuit the contactor 2 when switched on via break contacts 35 to a supply line 36 of the power source 9 is connected and only after switching on via normally open contacts 37 and auxiliary lines 38 directly to a second via the coil 28 of the contact relay 29 leading supply line 39/40 to the power source 8 can be connected. This circuit arrangement has the advantage that the inrush currents of the contactor coils from the coil 28 of the Contact relay 29 is kept away and so unfavorable stresses are switched off.

Claims (10)

Trigger 1. Electrical switching arrangement wherein a plurality of the same type, in any order becomes effective switching or measuring elements, in particular electric contactors, by means of them connected in this auxiliary circuits corresponding switching, control or control operations, characterized in that the various auxiliary circuits in terms of: CLAIMS Their voltage or current values in relation to the limit measured values (response values) of the associated measuring elements or to the control outputs of the associated switching elements and, with summation of their voltage or current values, with a common measuring device (11, 12; 28, 29), which triggers one or more control, switching or regulating processes depending on the sum of the voltage or current values of the auxiliary circuits that are switched on. 2. Switching arrangement according to claim 1, in which the voltage values of the auxiliary circuits are added, characterized in that the auxiliary circuits contain transformer-excited voltage sources (4, 21) when the associated switching or measuring elements (2, 17) are actuated, which via the auxiliary contacts ( 6, 7; 19, 20) are connected to one another and to the measuring device (11, 12) in such a way that they are connected in series regardless of the sequence in which they are switched on. 3. Switching arrangement according to claims 1 and 2, characterized in that that when applied to a contactor control, the contactor coils (3) as primary coils serve and excite secondary coils (4) lying in the auxiliary circuits, which through two pairs of normally closed contacts (6) and normally open contacts assigned to the contactors (7) can be switched. 4. Switching arrangement according to claims 1 and 2, characterized in that that when applied to mechanical switching or measuring elements, the voltage sources have secondary windings (21) of a common transformer having a primary winding (22), the normally closed contact (20) and Normally open contact (19) can be switched. 5. Switching arrangement according to claim 1, wherein the current values of the auxiliary circuits are added, characterized in that the auxiliary circuits are connected in parallel to a common power source (9, 26) and apart from the auxiliary contacts (24, 25; 8, 35, 37) that switch them, their have associated current value determining switching elements (30, 31, 32; 3). 6. Switching arrangement according to claims 1 and 5, characterized in that the current value determining Switching elements ohmic, inductive or capacitive resistors (30, 31, 32) are used. 7. Switching arrangement according to claims 1 and 5, characterized in that at Application to contactor controls the control circuits as auxiliary circuits and their contactor coils (3) serve as switching devices which determine the current value. B. Switching arrangement according to claims 1, 5 and 7, characterized in that each contactor has two rest contacts (35) and two make contacts (37) are assigned, of which the break contacts (35) serve to switch on the contactor coils (3), while the working contacts (37) after Maintain switching on of the contactor coil circuits as auxiliary circuits. 9. Switching arrangement according to claims 1 to 8, characterized in that the influenced by the sum of the voltage or current values of the auxiliary circuits, with Measuring device (11, 12; 28, 29) provided with control contacts directly or via an intermediate relay (14) Contactors (15) controls that switch one or more electric motors on, off or over. 10. Switching arrangement according to claims 1 to 9, characterized in that at Use for controlling the discharge of liquid or gaseous media in Depending on the supply of the media mentioned, the one provided with control contacts Measuring relay (11, 12; 28, 29) to a constant speed adjustable with respect to its speed, AC or three-phase motor (16), in particular a pole-changing three-phase motor, acts. References considered: U.S. Patent No. 2,809,312.