DE2756459C2 - - Google Patents

Description

The invention relates to a control switching device for control eration of the application of power to a load, such as. B. an electric motor or a heating device, in particular an electrical power circuit device with a Power contactor arrangement, their power switching contacts into the power supply lines between a load and a current source and are each connected in parallel bare semiconductor device for arcing-free switching assigned.

Known control switching devices or control contactors often have two groups of power contactors, one group for each direction of motor rotation. Because the bow education occurs above each switching or control contactor normally provided to protect the contacts hen. For example, a contactor has a three-phase motor three power contacts that close to the motor to rotate in a forward direction, and three additional cones clocks that close to the motor in the opposite So turning in the direction requires a total of six bows below pressure devices for the correct protection of the contacts.

From DE-OS 15 38 400 is a reversing device for change Known electric motors, in which a control circuit is intended for the use of power in an electrical Load with a power contactor with main contacts that between the source of an electrical current and a load are connected. The currents are switched on to a motor via power semiconductor switching elements. Such semiconductor switching elements on the one hand require one Protective measure for arcing-free switching, on the other hand however, they are very expensive and require complex heat dissipation have facilities if they are used for an extended period of time should absorb very high currents. From DE-AS 11 28 523 a control switching device with the characteristics mentioned above  len known, which has two power contactors. The like circuits are very expensive. At be knew device for reducing the effort two auxiliary Protect provided the one and the same valve either the Power switch contacts one of the two power switch protect assign, however, despite this reduction in The disadvantage is that two very complex and expensive expensive power contactors must be used.

In contrast, the present invention has the object reasons, a control switching device with the aforementioned To create features that are less complex and corresponding is inexpensive.

This object is achieved in that the power switching contactor arrangement only a single power contactor has a control contactor with changeover contacts in the current supply lines is provided, such that these depending on the Erre The state of the control contactor varies depending on the Load can be switched and that the power contactor and an interlocking circuit is assigned to the control contactor is such that the control contactor is neither energized nor ent can be excited as long as current through the power switching con clock of the power contactor flows.

According to the invention, a single load contactor is used, the application and removal of a force or performance to or from a load, e.g. an electric motor or a heater to control, and a control contactor is used to control the type of current to the load such as. the current direction to the motor or the voltage to Heater. Control circuit devices are fiction used to ensure that the contacts of the Do not open or close the control contactor while the current is at the load, and therefore according to the inven Arch suppression devices via the contact of the Control contactor unnecessary. Consequently, are according to the invention Arc suppression devices only for power switching  Protect provided, reducing the total cost of the control unit are reduced.

In a preferred embodiment of the invention, the Power or power through normally closed contacts the control contactor applied to the load, and that Power contactor is supplied with energy directly or excited. If desired, the type or the mark of the To change current, d. H. So the direction of rotation of the motor sweep or raise the temperature of the heater the power contactor over a group of normal wise open contacts of the control contactor excited where by ensuring that the control contactor is energized and those contacts that are connected to the load have been closed before the contacts of the power Contactors are closed. The control contactor circuit is provided with a time delay device, which, after the load has been switched off, causes the control Contactor remains energized long enough for the contacts of the Power contactor can open. That is why the contacts of the control contactor always in their ge wanted position during application and removal of force or power on or from the load, and the half are arc suppressors only over the contact of the power contactor required.

Use in the preferred embodiment of the invention The arc suppressors are similar to those like they are shown in U.S. Patent No. 39 82 137, according to which an auxiliary contact that connects each contact of the power contactor is used to control current to a Semiconductor device to regulate that is parallel to the main protect is connected. The auxiliary contacts are so out make sure that they close immediately before closing Eating or opening the main contacts and opening immediately bar after either closing or opening the main con clock to advance the control current to the semiconductor device see what reduces the voltage across the main contact  and arcing is prevented during contact is opened or closed, and to decrease the control current men when the contacts are closed to the semiconductors Protect facility and prevent it permanently Current is present when the main contacts do not close properly or close with a significant resistance in between.

Therefore, the aim is an improved and inexpensive tax circuit of the type to be provided for the control the application of an electric current to a load under Use a minimum number of arc suppressors directions, and in particular a service tax Circuit for an electrical load with a power switch contactor with main contacts between a source for elec electrical current and a load are connected, and auxiliary contacts that temporarily close before opening and closing the main contacts and opening shortly after opening and closing the main contacts, and a semiconductor arc suppression switching device, which depends on the activity of the Auxiliary contacts respond and parallel to the main contacts is closed to create a current path with lower Impedance around the main contacts for arc suppression where has a contactor contacts that between the elec trical power source and the load are connected for the Control of the label or the type of current to the load, whereby the current has a first kind or property, if the control contactor is deenergized or switched off, and one second property has when the control contactor is energized or is turned on, and a control circuit device which ver with the power contactor and the control contactor is bound to control its operation, the tax circuit device a circuit connection via the control Has contactor, whereby the control contactor neither can still be excited while current is flowing through the con cycle of the power contactor closes.

Further advantages, features and possible applications of the present invention result from the following description  exercise in connection with the drawings. Show it:

Fig. 1 schematically shows an electrical diagram of a motor control circuit tung Rich,

Fig. 2 is a schematic representation of a circuit switching circuit that is used to control the direction of motor rotation,

Fig. 3 protect the schematic representation of one of the power switching and the associated arc suppression sound processing device,

Fig. 4, the illustration of the operation of the auxiliary contact, which is associated with each of the power switching contactors,

Fig. 5 is a partial electrical schematic diagram of a heater control circuit, and

Fig. 6 shows a detail of the steering or control contactor showing the anchoring or clamp bracket to prevent short circuits.

In the following a preferred embodiment of the inven tion is explained in more detail as an example. Fig. 1 shows an embodiment of the invention, namely a three-phase motor 10 with three windings 11 , 12 and 13 , which are connected to the connections 16 , 17 and 18 , which in turn are connected to an AC power source 20 , via input connection connections 21 , 22nd and 23 .

The current for the motor 10 is controlled by means of the power switching contactor 30 , which has a plurality of normally open switching contacts 32 , 33 , 34 , the single-pole switch contactor 35 and the coil 36 . The switch contacts 32-34 are preferably provided with arc suppressors 37-39 , the details of which are described below.

The direction of rotation of the motor 10 is controlled by a control switching contactor 40 . This contactor has four double or changeover contactors 42-45 and a coil 46 . When the terminals 22 and 23 are in the de-energized state, they are connected to the terminals 17 and 18 via the normally closed elements of the contactors 42 and 43 and thus allow the motor 10 to rotate in the forward direction; and when the relay 40 is energized; the connection between the terminals 22 and 23 and the terminals 17 and 18 is reversed so that the motor rotates in the opposite direction.

The circuit shown in Fig. 1 is designed so that the application and removal of the current to the motor 10 and of this always takes place via the contacts of the power contactor 30 ; the position of the contacts of the control contactor are not changed when power is applied to the motor.

Control circuit devices are provided for the control of the power contactor and control contactor for control the direction of rotation of the motor to prevent the Control contactor contacts from one position to the other be switched while current is supplied to the motor.

The control circuit device has the circuit arrangement shown in FIG. 2, which preferably has a stop button 50 with the normally closed contacts 51 ; further includes a (FWD) forward key 52 with the normally open contacts 53 and the normally closed contacts 54 ; and a (REV) reverse button 55 with the normally closed contacts 56 and the normally open contacts 57 . AC power is applied to the input terminals 60 and 61 , and when it is desired to rotate the motor 10 in the forward direction, the push buttons 52 are depressed and the output terminal 62 is electrically connected to the terminal 60 via the normally closed ones Contacts 51 and 56 and the now closed contacts 53 brought the forward button 52 .

According to Fig. 1 of the terminal 62 is of the contactor connected via the normally closed contacts 45 and ge with a side of a bridge rectifier 70 40. The other side of the bridge rectifier is connected to the common United connection terminal 61 . The capacitor C 1 serves as a hum filter to prevent the contactor from vibrating or rattling. Thus, when the forward button is pressed, current is applied to the contactor coil 36 to excite this switching protective and provide electrical connections Zvi rule the terminals 21-23 and the windings of the motor 10 degrees.

A hold circuit is provided over the normally open contacts 35 of the contactor 30 , one contact of which is connected to the connection 72 , the other contact being connected to the normally closed contacts 44 of the contactor 40 and thus to the connection 73 , thereby making a parallel connection Current path around the contacts 53 ( Fig. 2) is provided. Thus, when the forward button is pressed once, the contactor 30 remains energized until either the stop button 50 or the reverse button 55 is operated. Depressing the stop button 50 decreases the holding current from the contactor 30 , this is de-energized and the contacts 32-35 open.

If it is desired that the motor rotate in the reverse direction, the reverse button 55 is depressed. As a result, the contacts 56 ; and thus the power to the coil 36 is un extracted from the contactor 30 (assuming that it was energized); and at the same time the contact 57 is closed and thereby connects the connection 60 to the connection 71 via the contacts 54 of the key switch 52nd

The connection 71 is connected to one side of the bridge rectifier 75 , the other side of which is connected to the common connection 61 . The output of the rectifier 75 is connected to the coil 46 of the contactor 40 and causes it to be energized after a time delay which is determined by the value of the capacitor C 2 and the resistor R 1 , whereby the connection between the terminals 22-23 and the connections 17-18 is reversed. This time delay is sufficient to give the possibility that the contactor 30 is de-energized and the arc suppression circuit out of action before the contactor 40 is energized, whereby the contacts 42-44 of the control contactor 40 are protected. When the contactor 40 is energized, current is passed to the bridge rectifier 70 through the normally open contacts 45 so that the contactor 30 is energized and power is applied to the motor 10 .

The holding current for the contactor 40 is from the terminal 72 through the contacts 35 of the contactor 30 and the normally open contacts 44 of the contactor 40 to the terminal 76 , which means that a parallel path for the contacts 57 is seen easily.

When the stop button 50 is depressed, power is drawn to both contactor coils and the contactor 36 is turned off, which opens its contacts or switch contacts 32-35 . However, the contactor 40 remains energized for a short time, due to the action of the capacitor C 12 , which therefore acts as a time delay device and ensures that the contacts of the contactor 40 open after those of the contactor 30 . Thus, any arcing that may occur due to the opening of the circuit to the motor is handled by contacts 32-34 of the power contactor rather than contacts 40 , and for this very reason the contactors of the power contactor are preferably with arc suppressors 36-38 see.

Thus, when the motor 10 is to be rotated in the reverse direction, the contactor 40 is first energized or attracted, and all of its contacts close before the contactor 30 is energized.

Fig. 9 is a schematic representation of one of the contacts 32 of the contactor 30 and its associated arc suppressor 37th The contact 32 is shown, for example, although it is understood that the contactor 30 has three similar contacts in a stacked position, each having its own arc suppression circuit.

The coil 36 of the contactor 30 is magnetically coupled to a loading 80 and pulls it down when the contactor is energized. The fitting rotates about a swivel position 81 and is pressed forward by a spring 82 from the coil. An insulated hinge part 83 is pivotally attached to the end of the upper contact bracket 85 . The part 83 also extends upwards and engages with similar brackets for the other contacts of the contactor.

The contact 32 has a first main contact element 90 , which is carried by the contact bracket 85 , and has a second main contact element 92 , which is arranged directly opposite this and is supported by a contact bracket 95 . Both contact brackets 85 and 95 have a sufficient cross-sectional area to conduct the motor current on a continuous basis and are nevertheless elastic or flexible enough to bend during the operation of the contactor.

As shown in Fig. 4, the contact bracket 85 extends through the joint or connection 83 , and the end of the bracket 85 forms an auxiliary contact 96 which is spaced from a fixed contact 97 .

The contact clip 85 also passes through an opening 99 in a fixed, insulated support part 100 . The part 100 it also extends upwards and serves in a similar manner with respect to the other contacts of the contactor.

The arc part 101 of the opening 99 is so arranged with respect to the contact bracket 85 that it engages with the bracket as soon as the coil 36 pulls the fitting and thus the part 83 down when the contactor is energized. As a result, the contacts 96 and 97 immediately close before the contacts 90 and 92 close, as shown by the broken line 85 a ; therefore contacts 90 and 92 engage and close the main circuit; and finally contacts 96 and 97 open as shown by dashed lines 85b. On the other hand, when the contactor is energized, contacts 96 and 97 engage similarly as soon as the fitting 80 begins to move upward; contacts 90 and 92 then open; and then contacts 96 and 97 open. We return again to FIG. 3, according to which the main connections of the triac 110 are parallel to the contactor 32 , the control electrode of the triac being connected to the contact 97 . During the excitation of the contactor, control current is thus fed to the triac 110 immediately before the closing and during the closing of the main contact elements 90 and 92 of the contact 32 , and the control current is then removed, which gives the possibility that the full current through the main contacts is performed and a surface eats or etching is caused, which may be necessary on the upper surface of the main contacts, so that they can then carry the full load. By removing the control current after the main contacts have closed, the triac ceases to conduct current at the first zero crossing of the current, and if the main contacts have developed a high resistance, the triac is not forced to carry current for a considerable time.

After the contactor has been de-energized or switched off, the control current to the triac is provided via contacts 96 and 97 , as soon as the contactor fitting 80 begins to move upwards, contacts 90 and 92 then open while the triac is fully in operation; and after the contacts are fully opened, contacts 96 and 97 open and take control current from the triac.

Those skilled in the art will recognize that other arcing suppressors could be used in conjunction with contacts 32 and 34 of contactor 30 , or that these contacts could be constructed to handle any arcing that occurs when power is supplied to motor 10 is switched. The control contactor 40 , on the other hand, can have a simpler and cheaper construction, and the total cost of a contactor constructed in accordance with the invention can be lower and the performance can be greater than that of the known devices. Also, the contactor described above is smaller than the known devices. For example, a contactor from this design, NEMA, size 2, takes up about 226 cm ² (35 square inches) less area than a similarly calculated contactor, which is constructed according to conventional standards.

Fig. 5 illustrates another embodiment of the inven tion, in which a load, in this case an electric heater, designated 110 , is connected to the source of an electrical current 115 by means of contacts 132 and 133 of a power contactor 130 . The contacts 132 and 133 are provided with arc suppressors 37 and 38 , respectively, which operate in the manner previously described. The current source 115 is shown as a Y-connected transformer secondary part with output connections 120-123 , the output connection 122 being a common connection (center point). For example, the voltage between terminals 122 and one of terminals 120 , 121 and 123 may be approximately 277 volts, while the voltage between terminals 120-121 , 121-123 and 123-120 may be approximately 480 volts, although it is understood that other voltage levels can be used.

The control contactor 140 controls the property or type of current applied to the load 110 . When the contactor 140 is de-energized, a voltage having a first property, namely 277 volts, is connected to the load from terminal 122 via the normally closed contacts 143 , and when the contactor 140 is energized, a voltage of a second property, namely 480 Volts, applied across the normally open contacts. Therefore, the magnitude of the current flowing through the heater 110 depends on the control contactor.

The control contactor 140 also has auxiliary contacts 44 and 45 , and the power contactor 130 has auxiliary contacts 35 that operate in the same manner as the auxiliary contacts of the same reference number as shown and described in connection with FIG. 1.

In operation, the contactor 140 is controlled in the same manner as the contactor 40 of FIG. 1, ie the contactor is neither energized nor de-energized while current flows to the load. The circuit shown in FIG. 1 can be used to ensure that the contacts of the contactor 130 , which include the arc suppressors 37 and 38 , bear the brunt of controlling current flow and that the contacts of the contactor 140 never open or close while current flows through them.

Fig. 6 is an enlarged view of the control contactor 140 showing the details of its construction. The contactor has a coil 146 which is magnetically coupled to a fitting 150 to pull the fitting down when the contactor is energized. The fitting is biased away from the coil by means of a spring 151 . An insulated connection 152 connects the fitting to the outer end of a movable contact bracket 155 , which is seen with an upper contact part 156 and a lower contact part 157 . The contact bracket 155 is flexible and is held at its other end between insulated spacer blocks 160 , which are supported on the arm 162 .

The contactor also has an upper flexible contact bracket 165 which has a contact portion 166 which, in the normally closed position (as shown) makes contact with the contact portion 156 to provide a current path between the terminals 122 and 124 . The contactor also has a lower flexible contact bracket 167 , which has a contact part 168 at its end, which is engaged by the contact 157 when the contactor is excited or engages with it to provide a current path between the terminals 123 and 124 . Both contact brackets 165 and 167 are supported within the insulated spacers 160 as shown .

The contacts 156 and 166 or 157 and 158 can be welded together sufficiently that they will no longer separate after the contactor has either been energized or de-energized. Should this happen and the center contact bracket should move sufficiently to allow contact with the other contact, then there would be a short circuit between the connections 122 and 123 . Referring briefly to Fig. 5, it is noted that these terminals are connected via a turn of the power source 115 and that this situation could cause considerable damage to both the control contactor and the power source.

According to the invention, therefore, an expansion bracket 170 is provided, which is formed from a fairly inflexible heavy steel part and extends 160 from the space between the insulated spacing outwards and then downwards, the end being bent upwards and arranged close to the contact 166 at is. In the deenergized state of the contactor, the contact member occurs 156 in engagement with the contact 166 and makes the contact bridge 165 be bent slightly upwards, and therefore the end of the spreader bar 170 is spaced from the lower surface of the contact clip 165th However, when the contactor is energized, the contact bracket 155 moves downward, but the contact bracket 165 is prevented from moving downward by the end of the spreading bracket 170 .

In a similar manner, a lower expansion bracket 175 is assigned to the lower contact bracket 167 , and its end is arranged next to the contact part 168 . When the contactor is energized, the contact 157 engages the contact member 168 and causes the flexible contact bracket 167 to move downward and somewhat from the end of the expansion bracket 175 . However, when the contactor is de-energized, the stirrup 175 prevents the contact 168 from moving upward, and if a weld between the contacts is strong enough, it also prevents the contact bracket 155 from moving upward enough to provide a current path between share the contact 156 and 166 to create.

A similar arrangement could be used for the contacts 42 and 43 in the control contactor 40 shown in FIG. 1 to prevent accidental shorting between the terminals 22 and 23 .

Claims (10)

1. Electrical power circuit device with a Lei stungs contactor arrangement ( 30 ), the power switching contacts ( 32 , 33 , 34 ) in the power supply lines between a load ( 10 ) and a current source ( 20 ) are connected and each one in parallel switchable semiconductor device ( 37 , 38 , 39 ) for arcing-free switching is assigned, characterized in that
that the power contactor arrangement has only a single power contactor ( 30 ),
a control contactor with changeover contacts is provided in the power supply lines, such that these can be connected to the load differently depending on the excited state of the control contactor,
the power contactor ( 30 ) and the control contactor ( 40 ) is assigned a locking circuit ( 50-57 ) such that the control contactor can neither be excited nor ent excited as long as current through the power switching contacts ( 32 , 33 , 34 ) of the power contactor flows. 2. Device according to claim 1, characterized in that the load is an electric motor ( 10 ) and that the control contactor ( 40 ) controls the direction of current flow through the motor ( 10 ) such that when the control contactor is de-energized ( 40 ) the motor ( 10 ) rotates in one direction and, when the control contactor ( 40 ) is excited, the motor ( 10 ) rotates in the opposite direction. 3. Device according to claim 1, characterized in that the load is an electric heating device ( 110 ) and that the control contactor ( 140 ) controls the voltage, wel che on the heating device ( 110 ) is given, and that when the control is excited Contactor ( 140 ) the voltage to the heater ( 110 ) has a first value and when the control relay ( 140 ) is de-energized the voltage applied to the heater ( 110 ) has a second value. 4. Device according to one of claims 1-3, characterized in that the power contactor ( 30 ) has contacts ( 32-35 ) which are connected between the electrical power source ( 20 ) and the load ( 10 ) for the control the application of the power to the load ( 10 ) that the control contactor ( 40 ) has contacts ( 42-45 ) which are connected between the power source ( 20 ) and the input terminals ( 16-18 ) of the load ( 10 ) for controlling the property of the current flow through the load ( 10 ), the current having a first property when the control contactor ( 40 ) is de-energized and a second property when the control contactor ( 40 ) is energized, and that the control circuit ( 50-57 ) is connected to the power contactor ( 30 ) and the control contactor ( 40 ) for controlling the operation thereof and that the control circuit has a first circuit connection through the control contactor ( 40 ), whereby there nn, if current of the second property is desired, the contacts ( 32 , 35 ) close the power contactor ( 30 ) after the control contactor ( 40 ) is energized and that the control circuit further a time delay device ( C 2 , R 1 ) has to delay the de-excitation of the control contactor ( 40 ) until after the contacts ( 32-35 ) of the power contactor ( 30 ) have opened and the current flowing to the load has been completely removed. 5. Device according to one of claims 1-4, characterized in that each power switch contact ( 32-35 ) of the power contactor ( 30 ) arc suppressors ( 37-39 ) are assigned. 6. Device according to one of claims 1-5, characterized in that the arc suppression device ( 37-39 ) auxiliary contacts ( 96 ) on the power contactor ( 30 ) have semiconductor devices ( 110 ) whose power-carrying connections over the Power contact ( 32 ) are connected and with a gate connection, which is connected via the auxiliary contacts ( 37 ) to a gate excitation signal, and an actuating device has contacts for closing the auxiliary contacts immediately before either closing or opening the contact and before opening the auxiliary contact immediately after either closing or opening the contact, temporarily reducing the potential across the contact to prevent arcing during opening or closing, and not holding the gate excitation signal when the power contact is closed, thereby counteracting the semiconductor device ( 110 ) Overload is protected in the event that the power contact should develop significant contact resistance or should not close. 7. Device according to claim 4, characterized in that a time delay device of the control device for its de-energizing delay is assigned a time which is longer than that time which is required for de-energizing the power contactor ( 30 ). 8. Device according to one of claims 1-7, in particular for Applying power to a three-phase electric motor and to control its direction of rotation, characterized by first, second and third power contactor devices, between an electrical power source and the motor connected arc suppression devices that connected across each power contactor, he first, second and third motor power input connections, Means for connecting the first power switching protective devices with the first power input connection, Control contactor devices, the second and third power contactor device with the second and third power input connector in a first com connect bin when not in use, so, that the motor rotates in a forward direction, and for that Connection of the second and third power contactors facilities with the second and third power input connections in a second combination when actuated are such that the motor turns in the opposite direction, a power contactor actuator device for the Actuation of the first, second and third power switching protective devices such that performance at first Power input connection and to the control contactor control contactor actuator directions for the actuation of the control contactor directions, devices for excitation of the Contactor actuators directly, such that the first, second and third power contactor device device for the forward rotation of the motor and by means of excitation of the control contactor loading actuating devices and the power contactor actuator devices such that the first, second and third th power contactor devices are actuated, after the control contactor contact device is actuated  and institutions that cause the tax Contactor device remains activated until after the Ab circuit or disengagement of the first, second and third contactor devices, whereby the Actu supply and its opposite of the control contactor device not done while performance is up to them, which means arcing over the control contactor device is prevented. 9. Device according to one of claims 1 to 8, characterized in that the contactor has a coil, a magnetically coupled with this for actuation by this fitting, has a movable contact bracket gel, which is connected to the fitting by an insulated connection is, wherein the contact bracket has a contact near its end, and has a flexible len contact bracket, which is arranged at a distance from the movable contact bracket, and has a contact for engagement with the contact on the movable contact bracket when the Fitting is in a first position, and that an expansion bracket ( 170 , 175 ) made of quite inflexible material stretches next to the flexible contact bracket ( 165 ) and has an end which is arranged next to the contact ( 156 , 166 ) and prevents that the flexible contact clip ( 165 ) follows the movable contact clip ( 155 ) when the fitting ( 150 ) moves into a second position in d em moves when the contacts are welded together. 10. Device according to one of claims 1-9, characterized in that the contactor has a second flexible contact bracket ( 167 ) which is arranged at a distance from the first movable contact bracket ( 165 ) and has a contact for engagement with the contact on the movable contact bracket when the fitting is in the second position and a second spreader bracket ( 175 ) is associated with the second flexible part to prevent it from following the movable contact bracket when the fitting moves from its second position to its first Moved position, which prevents a current path between the flexible contact clip and the second flexible contact clip if the contacts are welded.