EP0317660B1 - Contactor - Google Patents

Abstract

In a contactor (1) having a housing, in which a magnet system (6, 7, 13) is accommodated towards the mounting side and a contact system (19, 20, 21, 24, 25, 28, 81), which can be operated by the magnet system, is accommodated at a distance from the mounting side, thermal trip devices (73) and magnetic trip devices (49) being provided for each phase, which trip devices act on the contact system by means of an operating device (53, 54, 70, 48), in order to improve the switching reliability it is proposed that additional contacts (34, 76) for each phase and for the coil connection of the magnet system be provided in addition to the contact system and that the thermal trip devices, the magnetic trip devices and the operating devices be arranged and designed such that the additional contacts are forced to open in the event of tripping and switching-on again is possible only when the main contacts of the contact system are open. <IMAGE>

Description

The invention relates to a contactor with a housing, in which a magnetic system and at a distance from the mounting side a main system with main contacts with double contact interruption having contact system are housed, on the mounting side to a magnet system, thermal triggers and also within the housing for each phase Magnetic triggers are provided, which act on the contact system by means of an actuating device and are based on EP-A-0 185 107.

Various designs and types of contactors and motor protection switches are already known. A motor protection device normally consists of a contactor, to which a separate thermal motor protection is assigned, which is housed in a special housing. The entire contact system and the magnet system by which the contact system is actuated are then accommodated in a single housing, specifically the magnet system is either on the mounting side of the contact system or on the side of the contact system remote from the mounting side, that is to say above it arranged. The movable armature of the magnet system is connected to the contact bridge holder of the contact system via a coupling. In a further design, a thermal motor protection part is also accommodated in the housing, which only triggers if the current load or thermal load exceeds a certain level. In spite of the large construction costs, this thermal motor protection works relatively sluggishly in practice, because the current load or the thermal stress usually also increases very slowly. To the electric motor in question also against sudden disturbances, e.g. B. To secure short circuits, a separate fuse is still required for this, which has so far been housed in a separate housing outside of the previously described shooter housing. In order to be able to make the necessary electrical connections, a total of eighteen connections are required.

It is also known to connect a separate motor protection switch to a normal contactor consisting of a contact system and a magnet system via electrical lines. This requires a total of twelve connections, to which electrical lines must be connected.

In both types, the wiring is cumbersome and time-consuming, and it is not only a cost of materials for the electrical lines, but also for the many connections to the device parts. Apart from this installation effort, there is also a lot of space in these multiple devices, e.g. B. needed for accommodation in a control cabinet.

Another contactor known from EP-A-0 185 107 is of relatively compact design due to its construction, so it requires only little space on a mounting wall or in the control cabinet and the wiring can be carried out largely within the contactor. In addition to the thermal triggers for three phases, short-circuit fast triggers or magnetic triggers are also provided, which act on a switch lock and thus on the contact system and, in the given case, switch off the motor protection switch. An undervoltage or shunt release can also be provided. The main disadvantage of this contactor serving as a motor protection switch, however, is that it can only be switched on manually by means of the switch-on button and a deliberate switch-off can only be carried out manually by means of a switch-off button, apart from the automatic switch-off by the motor protection described.

In practice, there is also a considerable need for cases in which the contactor should also be switched on or off mechanically. There is also a need for the contactor to be switched on or off from another suitable location, e.g. B. when installing the contactor in a control cabinet together with many other switching devices, then switching on or off mechanically or manually from another location, for. B. on a machine tool in which z. B. the electric motor to be protected is located.

In order to create a contactor that is as compact as possible with the least possible external wiring effort, it was proposed in EP-A-0 237 607 to provide a contact system in a housing near the mounting side and an actuating device vertically above it, with one side of the actuating device at each phase Thermal triggers and magnetic triggers are arranged, which are operatively connected to the actuator. On the other side of the actuating device, an electromagnetic drive is arranged, the armature of which is connected to an extension piece of a common contact bridge holder of the contact system via articulated toggle levers. A slide is also provided, on which the toggle levers on the one hand and the thermal and magnetic triggers on the other hand engage.

Finally, from DE-C-845 974 a motor protection switch with quick release and double contact break in the phases is known. The double contact interruption occurs at the main contacts or the work contacts. For this purpose, as is well known for contactors and in particular also for motor protection switches, two fixed contact rails are provided at a distance from each other for each phase, which cooperate with a movable contact bridge, so that two contacts are provided for each phase are. But also here the quick release takes place by means of magnetic triggers, which act directly on the respective contact bridge with the interposition of mechanical components and open the double contact by lifting off the contact bridge. In the event of a malfunction, in which such a magnetic release comes into effect, a mechanical device with two rockers is activated, so that the circuit of the coil of the electromagnet is interrupted, the armature drops and the contact bridges are opened in the other phases . A thermal release is also provided, which can also switch off the motor protection switch in the event of a fault via the mechanical actuation device.

In all the known types or constructions of the contactors, it is assumed or assumed that the contacts of the contact system actually always open in the event of overload and tripping. In the case of contactors equipped with thermal and magnetic triggers, these only act on the usual contact system using an actuating device. Due to the very large number of switching operations that the contact system has to carry out, wear occurs over time, which is promoted or accelerated by numerous mechanical influences and also by arcing. The contacts can therefore be welded at unpredictable times, so that ultimately there is no optimal switching reliability.

In contrast, the invention is based on the object of creating a compact contactor with little external wiring with integrated thermal and magnetic triggers, which ensures great switching reliability.

Starting from the contactor explained at the beginning, the task is solved in that in the current path Main contacts of the contact system additional contacts which are constantly closed during normal switching operation are provided for each phase and for the coil connection of the magnet system, and that the thermal triggers, the magnetic triggers and the actuating device are arranged and designed in such a way that all additional contacts when triggered as a result of an accident forcibly opened.

Because the additional contacts can remain closed during the normal switching operation of the contactor, they are therefore subject to virtually no wear, so that there is no danger of these additional contacts being welded for this reason. Even this danger is eliminated in that the additional contacts are forcibly opened in the event of an overload.

Advantageous embodiments of the contactor according to the invention result from the subclaims.

• Figur 1 ein Schützteil mit Magnetsystem und Kontaktsystem im Vertikalschnitt,
• Figur 2 ein Schützteil gemäß Figur 1, jedoch mit einer Ergänzung des oberen Gehäuseteiles,
• Figur 3 das obere Gehäuseteil im Vertikalschnitt mit Darstellung der Spulenanschlüsse,
• Figur 4 ein weiteres Schützteil mit Darstellung der thermischen und magnetischen Auslöser sowie mit einem zusätzlichen Kontakt im Vertikalschnitt,
• Figur 5 einen Vertikalschnitt durch ein gesamtes Schütz, welches aus den Teilen nach den Figuren 1 bis 4 zusammengesetzt ist,
• Figur 6 einen Vertikalschnitt eines Schützes entsprechend Figur 5, jedoch in einer anderen Ausführung
• Figur 7 ein Schützenteil entsprechend Figur 4, jedoch in der Ausführung nach Figur 6,
• Figuren 8 bis 10 eine andere Ausgestaltung der Betätigungsvorrichtung mit thermischen und magnetischen Auslösern in unterschiedlichen Betriebsstellungen,
• Figur 11 eine perspektivische Darstellung eines Schiebers mit einer Sperre und
• Figur 12 eine Einzelheit aus Figur 6 mit einer Sperre in vergrößertem Maßstab.

In the drawing, embodiments of the invention are shown in the diagram, namely show.

• 1 shows a contactor part with magnet system and contact system in vertical section,
• FIG. 2 shows a protective part according to FIG. 1, but with an addition to the upper housing part,
• FIG. 3 the upper housing part in vertical section showing the coil connections,
• FIG. 4 shows a further protective part with a representation of the thermal and magnetic triggers and with an additional contact in vertical section,
• FIG. 5 shows a vertical section through an entire contactor, which is composed of the parts according to FIGS. 1 to 4,
• Figure 6 is a vertical section of a contactor corresponding to Figure 5, but in a different version
• 7 shows a contactor part corresponding to FIG. 4, but in the embodiment according to FIG. 6,
• FIGS. 8 to 10 show another embodiment of the actuating device with thermal and magnetic triggers in different operating positions,
• Figure 11 is a perspective view of a slide with a lock and
• Figure 12 shows a detail of Figure 6 with a lock on an enlarged scale.

For the sake of clarity, individual parts of the contactor according to the invention are drawn out in FIGS. 1 to 4, while FIG. 5 illustrates a longitudinal section through the entire contactor composed of the individual parts according to FIGS. 1 to 4. The actual contactor 1 according to FIG. 1 has a lower housing part 2 and an upper housing part 3 with a division plane 4 which runs perpendicular to the image plane of FIG. 1. The housing parts can be connected to one another by conventional screwing. However, it is advantageous to use clamp-like connecting springs 10 with a crank 11 at the lower end and a support bow 12 at the upper end, so that a simple tool-free clamping of the housing parts is made possible, so that both simple assembly and disassembly is achieved. The lower housing part 2 has a lower fastening plate on the fastening side, which is provided with a quick fastener (not shown in detail) and is used for connection to a standard mounting rail. The magnet system consists of a core 6 with short-circuit rings 8 and 9, which is fastened in the lower housing part 2, and an armature 7 and a coil 13 movable in the upper housing part 3. The armature 7 is fastened to a connecting piece 14, from which lateral guide tabs 15 extend that enclose the anchor laterally. With the connecting piece 14, a plunger 16 is connected, which is extended upwards to a contact bridge holder and ends with a pushbutton 17 which protrudes outwards through an opening in the upper housing part and the height of which indicates the switching status of the contactor.

In the contact bridge holder of the plunger 16 there is a window 18 in which a contact bridge 19 with movable contact pieces 20, 21 is arranged so as to be vertically movable. The contact bridge 19 is under the pressure of a helical compression spring 22 with the interposition of a further bow spring 23, which serves for better mounting and guidance. Fixed contact rails 24 with fixed contact pieces are arranged to the contact bridge, of which only one rail is shown in FIG. 1. This leads to a terminal 26, which in turn carries a contact terminal screw 27. The terminal 26 is used to connect the external wiring, not shown.

Figure 2 shows some additions compared to Figure 1. As for the shooter part of Figure 1, it agrees with Figure 2 and the same reference numerals have been used for the same parts. 2 shows a further U-shaped fixed contact rail 29 with a fixed contact piece 28 on the upper side of the web 30 of the fixed contact rail 29. One end of a tension spring 35 is fastened to the lower end of the leg 31, while the other end of the tension spring is fastened to a pivotable one Contact rail 33 attacks. The pivot bearing of the contact rail 33 is located on the outside of the lower end of the leg 32, but with a certain small distance above the center line or pull line of the tension spring 35. In the drawn position, the contact rail 33 with the movable contact piece 34 is by the tension spring 35 pressed down. As soon as the contact with the contact piece 34 is forcibly opened, which will be described in more detail below, the contact rail is moved counterclockwise around the pivot bearing, so that the tension spring also moves over the corresponding dead center and then contributes to the sudden opening of the contact, until the contact rail is in the dot-dash position 33a.

A general explanation should be added at this point. In the figures, the electrical parts are only shown for one phase. Normally a contactor works with three phases, so that in practice it is perpendicular to Three contact bridges 19 with the respective compression springs are accommodated in individual windows of the common contact bridge holder of the plunger. Accordingly, three fixed contact rails 24 and 29 with separate terminals are arranged side by side. This also applies to the contact rails 33 with the movable contact pieces 34 and for the springs 35.

FIG. 3 shows a vertical section through the upper housing part 3, but compared to FIGS. 1 and 2 not in one plane of a phase, but in a plane in which the coil connections are located. The coil connections are of course only on one level, since only two connections are required. There are two coil connection terminals 36 and 38 with coil connection screws 37 and 39 fixed in the upper housing part 3. The coil connection screws 37 and 39 are accessible from above through holes for a screwdriver, the holes also serving as guides for the screwdriver. Furthermore, coil connecting rails 40 and 41 with vertical legs 42 and 43 are provided, the latter being connected to the coil. Advantageously, the coil connecting wires are not directly connected to the legs 42 and 43, but there are advantageously mutually not shown spring pieces that meet when the upper housing part 3 is placed on the lower housing part 2 and ensure a safe current transfer and at the same time facilitate assembly and disassembly. It is of particular importance that In the current path of the coil connections, an additional contact that is forcibly opened is provided. This additional contact is formed by a fixed contact piece 46 and a movable contact piece 47. The fixed contact piece 46 is attached to the top of a right-angled leg of the coil connecting rail 41, while the movable contact piece 47 is attached to the outer end of a contact spring clip 44. The contact end bracket is attached with its right end to a right-angled rail 45, which in turn is electrically conductively connected to the coil terminal 38. The slide 48 partially shown in FIG. 3, which will be described in detail below, serves to force the contact 46, 47 to open, so that the contact spring clip assumes the dash-dot position 44a in the open position and the coil connection is interrupted with certainty.

Another particularly important component of the contactor according to the invention is shown in FIG. Reference numeral 49 denotes a magnetic release, which essentially consists of a coil carrier 50, a coil 51 and a fastening part 52. With respect to the coil, an armature 53 is arranged axially displaceably, which has a window at the lower end and, as described below, interacts with an actuating device. The actuating device has a first angle piece 54 with a left leg 55. Furthermore, the angle piece has a web 58. The pivot bearing for the angle piece is provided with the reference number 57. At its outer, lower end the web 58 has an angled part 59 with a lug 60. Furthermore, a pressure spring 61 engages on the web 58, the other end of which is supported on the inner wall of the housing 87 and which tries to turn the angle piece 54 in the bearing 57 in a clockwise direction to pan. Below the first angle piece 54 there is a second angle piece 62, one leg 63 of which engages in the window 90 of the armature 53. The angle piece 62 is held in a pivot bearing 64 and it has a step 65. A compensation strip 66 is also attached to the angle piece 62, the lower free end of which rests on a spherical projection 68 of a lever arm 67 and serves for compensation with respect to the room temperature. The compensation strip 66 and the lever arm 67 are provided only once, while all the other parts which have been explained so far with reference to FIG. 4 and also explained below in this regard are provided in triplicate, as will be explained further below. The lever arm 67 is attached to a third angle piece 70 at 69. This angle piece 70 is connected at 71 to the upper angle piece 62. The outwardly angled leg of the angle piece 70 has an opening or a slot into which a web 72 of a thermal release 73 engages from above. The thermal trigger is attached to its upper end by a bracket 74. In the upper part of the component according to FIG. 4, a fixed contact piece 76 of a fixed contact rail 77 is also shown. This fixed contact rail 77 is essentially C-shaped and its leg 78 leads to a clamp 79 with a contact connection screw 80. The fixed contact piece 76 interacts with the movable contact piece 34 of the contact rail 33 already described. So this is an additional one Contact for one phase each, for a total of three additional contacts. As has already been indicated above, there is a magnetic release 49 and a thermal release 73 for each phase. All the other parts described for FIG. 4 are also provided in triplicate, that is to say simply for each phase, and perpendicular to the image plane at a distance from one another. Finally, it should be mentioned here that the fastenings explained at points 69 and 71 and their spacing from one another serve to protect the phase balance.

The mode of operation of the device according to FIG. 4 is essentially as follows. If an overcurrent suddenly occurs, for example from ten times the nominal current to a short circuit, the magnetic release 49 in the relevant phase comes into operation, that is to say the armature 53 is suddenly pulled up, so that the leg 63 of the second angle piece 62 about the pivot bearing 64 moves in the clockwise direction and the nose 60 is free relative to the step 65, so that the compression spring 61 also swings the first angle piece 54 around the bearing 57 in a clockwise direction. The left end of the leg 55 of the angle piece 54 engages in the slide 48, so that it is moved upward and triggers a double function, which will be explained in more detail below. A similar process takes place when a thermal release 73 responds in at least one phase when the overcurrent rises slowly, for example up to six to eight times the nominal current. This then presses with its web 72 the third angle piece 70 to the left, so that the second angle piece 62 again in the described clockwise direction moved and the contact is triggered.

Figure 5 now shows the overall contactor composed of the parts of Figures 1 to 4. The same reference numerals as in FIGS. 1 to 4 have been used for all parts. However, FIG. 5 essentially illustrates the double action of the slider 48. This is designed so that, as described, it is effectively connected to the left end of the leg 55 of the angle piece 54, that it also moves the contact rail 33 when it is moved upward takes forcibly upwards, so forcibly opens the contact between the contact pieces 34 and 76.

Finally, the slide 48 is extended upwards so far that it can perform a second function, namely also strikes under the contact spring clip 44 and thus opens the coil contact with the contact pieces 46 and 47. The action of the tension spring 35 causes the contact rail 33 to snap up into position 33a. After the malfunction has been remedied, the device can be switched on again by pivoting the contra-angle 54 counterclockwise, specifically on the top of the upper housing part a correspondingly configured restart button or a plunger 88 with a plunger head 89 (FIGS. 6, 11 and 12) is provided, above all, to return the contact rail 33 from the spread position 33a back to the original position. At the same time, this also brings the contact spring clip 44 back into the switched-on position.

The housing part 87 for receiving the contactor part according to FIG. 4 can optionally be designed differently. So it can with the lower housing part 2 can be integrated or it can be divided according to the lower housing part 2 and the upper housing part 3 or it can be manufactured as a separate housing part in order to be firmly connected to the other housing parts after the installation of the individual device parts. Finally, there is a particularly advantageous possibility of expanding the housing part 87 upwards and accommodating all additional contacts both for the phases and for the coil connection. Compared to the previously described exemplary embodiment, this requires only a relatively small redesign according to FIG. 7, so that a component is created which can also be retrofitted to conventional contactors. It is important that intermediate wiring with contact connection screws is omitted.

The contactor explained above embodies a number of properties and advantages. One shift is possible by hand. The contactor can also be switched on and off by remote control. Furthermore, overload protection of each individual phase is provided by both magnetic triggers and thermal triggers. The additional contacts per phase and in the coil connection are positively opened when tripped, so that a shutdown takes place in any case, even if the main contacts should be welded. The switching status of the contactor is constantly visible from the outside. The contactor can advantageously be used as a motor protection switch. Overall, despite all the possibilities, there is such a compact design that the contactor as a conventional Contactor can be attached to a standard mounting rail, for example, without requiring any significant space. The mostly standardized width of the contactors (perpendicular to the image plane) can be maintained so that the contactor can be placed close together with other, possibly conventional contactors, in a control cabinet or on a mounting plate. Finally, only the lowest possible wiring is required, namely two three, ie six, wiring connections with contact connection screws for the three phases and two further wirings with connection screws for the coil connection. All connection screws are freely accessible from the operating side.

The exemplary embodiment of the contactor according to the invention shown in FIGS. 6 and 7 largely corresponds to the contactor according to FIGS. 1 to 5, so that the same reference numerals have been used for all the same parts. Another design has received the fixed contact rail 81, which is also U-shaped, but with a vertical web in the drawing and two horizontal legs, the lower leg having a kink 83, which is used for pivoting a contact rail 82. As shown, a compression spring 84 is inserted obliquely between the upper leg of the fixed contact rail 81 and the inner end of the contact rail 82 and can be held by pins or projections on both sides. In this case too, the contact rail in the open position assumes approximately the position shown with the reference symbol 82a. The compression spring 84 is inserted between the fixed contact rail 81 and the pivotable contact rail 82 in such a way that it increases the contact pressure between the contact pieces 34 and 76 in the normal switched-on operating position, but increases after tripping via a Dead center position moved away and the opening force increased. In the opening or pivoting area of the contact pieces 34, arc quenching chambers or lamellae 85 can advantageously also be arranged.

FIGS. 8 to 10 illustrate, in comparison to FIG. 4, another simplified exemplary embodiment of an actuating device in three different operating positions. The same reference numerals as in FIG. 4 have been used for the same or equivalent parts. In this exemplary embodiment, magnetic triggers 49 and thermal triggers 73 are again present, one trigger per phase, that is, three triggers perpendicular to the image plane at a distance from one another, as has been explained above. According to FIG. 4, the actuating device also has an angle piece 54, the leg 55 of which engages with the left end in the drawing in a window of the slide 48 and which can be pivoted about a bearing 57. In this embodiment, however, a cranked lever 91 is provided, which is again held in the pivot bearing 64 and which, in the normal operating position according to FIG. 8, locks the angled part 59 of the angle piece 54 because the edge of the nose 60 rests on the adjacent edge of the step 65 . The left end of the cranked lever 91, which is expediently crowned on the underside, engages in a window 90 of the armature 53 or a lower extension of the armature. If a magnetic trigger 49 now responds, the armature is attracted. Thus, the cranked lever 91 pivots clockwise around the pivot bearing 64 and gives the angled part 59 of the Elbow 54 under the pressure of the spring 61 free, so that the slider 48, as described above, is suddenly moved up again and opens all the additional contacts described. This operating position is shown in Figure 10. On the other hand, when a thermal trigger 73 responds, the lower web 72 presses on a lug 94 of a pivot lever 93, which is held in a pivot bearing 71. Due to the action of the compression spring 92, the nose 94 of the pivot lever bears against the web 72 and, in addition, the pivot lever 93 with the ball 68 bears against a rail loaded by the spring 92, which in turn is fastened in the cranked lever. As described above, this rail 66 can also be designed as a compensation strip. By pivoting the thermal release with the web 72 in the direction of the arrow (FIG. 9) to the left, the pivot lever 93 pivots out in the corresponding direction, takes the rail 66 with it, as a result of which the cranked lever 91 is pivoted clockwise or in the direction of the arrow about the pivot bearing 64 is, so that the angle piece 54 comes back to the release position as described above and causes the contact opening of all additional contacts via the slide 48. Otherwise, the above statements in connection with FIG. 4 also apply to this exemplary embodiment according to FIGS. 8 to 10.

FIGS. 11 and 12 illustrate a particularly important embodiment in the diagram, which is also shown in principle in FIG. 6 in order to clarify the connection with the other parts of the contactor. These are shown in FIG. 6 Device parts are also to be used equally in the exemplary embodiment according to FIGS. 1 to 5. According to this embodiment, the slider 48 is designed as a flat, substantially rectangular plate which can be displaced between suitable guides, not shown, within the housing part 87 in the direction of the arrow 95. At the upper end, a plunger 88 is fastened with a plunger button for manual actuation, which projects outwards through an opening in the upper housing wall and which makes the respective operating position visible. The inward position indicates the normal on position. If the plunger 88 protrudes far up, you can see the release position in which all additional contacts are open.

The slider 48 has three windows 96, 97 and 98 in the lower area, into which the legs 55 (FIG. 4) or 99, 100 and 101 of the angle pieces 54 or 102, 103 and 014 engage. Approximately in the middle area, further windows 105, 106 and 107 are incorporated in the slide 48, through which the pivotable contact rails 33 (FIG. 4) or 109, 110 and 111 are guided. The same applies to the contact rails 82 in the exemplary embodiment according to FIG. 6. Depending on the spatial arrangement of the additional contacts 46, 47 or the contact spring clip 44 for the coil connection, a further window 108 is provided in the slide 48, which, however, is only shown in FIG For the sake of clarity and for better differentiation, it is drawn in an upper right projection, but in practice it can be arranged within the rectangular plate of the slider 48 and further down.

The contact spring clip 44 is passed through this window 108. The size of the window is to be adapted to the circumstances, so that the contact rails or the contact spring clip have a certain amount of play, but can inevitably be brought safely into the open position and when switched on again in the closed position.

It is also of particular importance that a lock is provided between the slide 48 and a suitable head part 112 of a common contact bridge holder of the contactor contact system. This head part 112 is shown only schematically in FIG. Figure 6 clearly shows, however, that this head part is a part which is connected to the plunger 16 and to the common contact bridge holder and thus to the armature 7 of the contactor. The lock is now arranged and designed such that the additional contacts, which have been described in detail above, can only be switched on again if all main contacts 20, 21, 25, 28 of the contactor contact system are open. The lock expediently has a cross slide 114. The cross slide 114 is provided after the slide 48 with an inclined surface 118 which interacts with another window 119 of the slide 48. At the opposite end, the cross slide 114 has a somewhat offset projection 115, which can be snapped into a notch 113 or an indentation or recess in the head part 112. The cross slide 114, as illustrated in FIG. 12, is provided with a compression spring 117, which is arranged such that it connects the cross slide 114 to the Tried to push slider 48. For this purpose, the compression spring 117 is used, for example, in an elongated rectangular recess in the cross slide, the right end of the compression spring being supported on the wall of the recess and being held immovably there, for example by a pin or the like. The left end of the compression spring is supported on a stop 121, which is connected to a guide 116, for example, in an embodiment not shown.

The cross slide 114 is advantageously held by a guide 116, which allows the cross slide to be displaced in its longitudinal direction and between stops, not shown, parallel to the displacement direction of the slide 48 and the head part 112.

The mode of operation of this constructional detail according to FIGS. 11 and 12 is essentially as follows, starting from the operating state shown in FIG. 12 and in which both all main contacts 20, 21 and all described additional contacts are open. The plunger head 89 is actuated by pressing it down to switch the additional contacts on or on again. The edge 120 on the upper edge of the window 119 reaches the inclined surface 118 of the cross slide 114, which is thereby displaced to the left against the pressure of the compression spring 117, so that the projection 115 engages in the notch 113. The additional contacts for the three phases are switched on without load, since the main contacts of the Contactors are open. The additional contact for the coil connection is closed, however, so that the contactor can now operate normally, ie can be switched on and off. At the same time, the actuating device moves into the locking position described, for example according to FIGS. 5 to 8. While the projection 115 of the cross slide 114 engages in the notch 113, when the slide 48 is pressed down, the outer edge of the inclined surface 118 bears against the left wall surface of the slide 48. If the contactor is now switched on, the plunger 16 with the head part 112 and with the common contact bridge holder moves down to the switch-on position, the latched cross slide being carried along on or with the guide 116 until the inclined surface 118 of the cross slide is in again the window 119 of the slide 48 can slide in, under the action of the compression spring 117. The projection 115 disengages, so that the contactor can now operate completely normally. If, in the event of tripping by the magnetic or thermal triggers described, the additional contacts for the three phases and for the coil connection have been opened, the slide 48, as described, is suddenly moved to the uppermost position according to FIG. 12 and the cross slide 114 in drawn position taken. If one or more main contacts of the contactor are now welded and the plunger 16 with the contact bridge holder and the head part 112 remain in the lowest position, it cannot be switched on again by pressing the plunger head 89, because then the left end face of the projection 115 of the cross slide 114 does not in the notch 113, but on the right outer Side surface of the head part 112 above the notch 113. Thus, the cross slide 114 cannot be shifted to the left and its right end remains in the window 119 of the slide 48 and thus blocks the shifting movement of the slide 48 into the switched-on position. Only after the fault has been completely eliminated can it be switched on again if the main contacts of the contactor are open.

In summary, the main advantages of the contactor according to the invention are emphasized here. The compactness of the contactor with all the functions described in a single device results in considerable connection savings and space savings for transport, storage and assembly in comparison with known contactors. There is one contact opening per current path - in comparison with known contactors - more. This results in a high degree of switching reliability, because it is ensured that one contact per current path always opens, even if one or more main contacts of the contactor are welded. The contactor itself can operate completely normally, taking into account that a contactor has a switching capacity of up to approximately 10 million switching operations during the normal service life. In contrast, the described additional contacts switch only in the event of an overload and are therefore only loaded to a relatively small extent, so that there is also a high degree of switching reliability. In addition, the additional contacts can only be switched on without load. This prevents bouncing. The entire actuator, which is also called Switch lock can only be effective with its thermal and magnetic triggers if it is overshot. Compared to known motor protection switches, in which an actuation of the complicated switching mechanism is required for each switching on and off, there is only a small switching cycle in the actuating device or the switching lock according to the invention. The compact construction of the contactor with a contactor part according to FIG. 1 which is quite normal per se results in the further advantage that additional parts, such as auxiliary contact blocks or modules, can be attached or constructed.

Claims (24)

1. Contactor with a casing (2, 3), in which towards the assembly side (5), a magnet system (6-9, 13) and at a distance from the assembly side (5), a contact system (19-21; 24, 25, 28, 29) able to be actuated by the magnet system (6-9, 13) and comprising main contacts (20, 21; 25, 28) with double contact breaking are located, likewise within the casing (2, 3, 87), thermal tripping devices (73) and magnetic tripping devices (49) being provided for each phase, which devices act by means of an actuating device on the contact system, characterised in that provided in the current path of the main contacts (20, 21; 25, 28) of the contact system (19, 20, 21; 24, 25, 28, 29) are additional contacts (33, 34, 76, 77; 44, 46, 47), which are permanently closed during the normal switching operation, for each phase and for the coil connection of the magnet system, and that the thermal tripping devices (73), the magnetic tripping devices (49) and the actuating device (48, 55, 57, 58, 62, 70) are arranged and constructed so that at the time of tripping all the additional contacts (33, 34, 76, 77; 44, 46, 47) are forcibly opened as a result of a disturbance.
2. Contactor according to Claim 1, characterised in that the actuating device comprises a first angle member (54), which acts by an inwardly directed leg (55) on a slide (48) and whereof the web (58) is locked in the normal operating position by a second angle member (62) and released at the time of tripping of at least one magnetic or thermal tripping device (49; 73), and that the slide (48) is designed so that the additional contacts (34, 76; 46, 47) of the phases and of the coil connection can be opened forcibly by the slide.
3. Contactor according to Claim 1 or 2, characterised in that acting on the first angle member (54) is a compression spring (61), which is located between the central part of the web (58) of the first angle member (54) and the inner wall of the casing.
4. Contactor according to Claim 2 or 3, characterised in that the second angle member (62) acts by a leg (63) on the armature (53) of the magnetic tripping device (49), is held in a swivel bearing (64) and is connected to the other leg by a third angle member (70), which in turn acts on a thermal tripping device (73).
5. Contactor according to one of Claims 2 to 4, characterised in that the second angle member (62) is provided with a step (65), in which the nose (60) or the outer end of the web (58) of the first angle member (54) may snap into abutment.
6. Contactor according to one of Claims 2 to 5, characterised in that attached to the second angle member (62) is a compensation strip (66) for compensation to the ambient temperature, whereof the free end bears against a ball (68) of a lever arm (67), which is connected to the third angle member (70) at a point (69), whereof the distance from the swivel bearing (64) of the second angle member (62) is greater than the distance of the attachment point (71) of the two angle members (62, 70) to each other and this swivel bearing (64).
7. Contactor according to one of the preceding Claims, characterised in that tilting contact bars (33; 82) are provided for the formation of the additional contacts for the phases, at the free ends of which bars contact pieces (34) are provided, which cooperate with fixed contact pieces (76) of fixed contact bars (77).
8. Contactor according to Claim 7, characterised in that springs (35; 84) act on the contact bars (33; 82).
9. Contactor according to Claim 8, characterised in that the spring (35) is constructed as a tension spring and located so that in the normal operating position it increases the contact pressure, but after tripping moves beyond a dead-centre position and increases the opening force.
10. Contactor according to Claim 8, characterised in that the spring (84) is constructed as a compression spring and is inserted between the fixed contact bar (81) and the tilting contact bar (82) so that in the normal operating position it increases the contact pressure, but after tripping moves beyond a dead-centre position and increases the opening force.
11. Contactor according to one of the preceding Claims, characterised in that the additional contact for the coil connection is formed by a contact spring clip (44), which is connected at one end to a current-carrying bar (45) of the coil connection and at the other free end supports a movable contact piece (47), which cooperates with a fixed contact piece (46) of a coil connection bar (41, 43).
12. Contactor according to one of Claims 2 to 12, characterised in that the slide (48) comprises a plunger (88), which projects outwards through a window in the casing.
13. Contactor according to one of the preceding Claims, characterised in that the additional contacts (33, 34, 76, 77; 44, 46, 47), the thermal tripping devices (73), the magnetic tripping devices (49) and the actuating device (48, 55, 57, 58, 62, 70) are located in a separate casing part (87), which is adapted to the contactor casing (2, 3) and detachably connected thereto.
14. Contactor according to one of the preceding Claims, characterised in that arc quench chambers (85) are arranged in the tilting region of the contact bars (33; 82) of the additional phase contacts (34).
15. Contactor according to Claim 1, characterised in that the actuating device comprises an angle member (54), which acts by an inwardly directed leg (55) on a slide (48) and whereof the web (58) with a bent part (59) is locked by a cranked lever (91) in the normal operating position.
16. Contactor according to Claim 15, characterised in that a tilting lever (93) held in a bearing (71) is provided, which lever bears by a nose (94) against a swinging-out web (72) of a thermal tripping device (73) and at the time of tripping acts on a spring-loaded bar (92) or a compensation strip (66), which is attached to the cranked lever (91).
17. Contactor according to one of Claims 2 to 16, characterised in that the slide (48) is constructed as a flat plate guided parallel to the displacement direction (95), which plate comprises windows (96, 97, 98) or recesses, in which the legs (55; 99, 100, 101) of the tiltable angle members (54; 102, 103, 104) engage.
18. Contactor according to Claim 17, characterised in that the slide (48) comprises further windows (105, 106, 107; 108), through which the tilting contact bars (33; 82; 109, 110, 111) as well as the contact spring clip (44) are guided.
19. Contactor according to one of Claims 2 to 18, characterised in that provided between the slide (48) and a head part (112) of a common contact bridge holder of the contactor contact system is a barrier, which is arranged and constructed so that reclosing of the additional contacts (33, 34, 76, 77; 44, 46, 47) is only possible when all the main contacts (20, 21, 25, 28) of the contactor contact system are open.
20. Contactor according to Claim 19, characterised in that the barrier is constructed as a transverse slide (114).
21. Contactor according to Claim 19 or 20, characterised in that the head part (112) is provided with a notch (113), an indentation or recess, in which a projection (115) of the transverse slide (114) may be engaged.
22. Contactor according to one of Claims 19 to 21, characterised in that towards the slide (48), the transverse slide (114) comprises an inclined surface (118), which cooperates with a window (119) in the slide (48).
23. Contactor according to one of Claims 19 to 22, characterised in that the transverse slide (114) is provided with a compression spring (117), which is constructed so that it pushes the transverse slide (114) towards the slide (48).
24. Contactor according to one of Claims 19 to 23, characterised in that the transverse slide (114) is held by a guide (116), which allows a displacement of the transverse slide (114) in its longitudinal direction and between stops parallel to the displacement direction of the slide (48) and of the head part (112).

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