DE942755C - Automatic circuit breaker for the automatic interruption of an electrical circuit in the event of overload - Google Patents

Description

There are already circuit breakers for automatically breaking the circuit in the event of overload known, which exploit the properties of ferromagnetic metals or metal alloys, whose ferromagnetism is a function of temperature. This is done in a known manner in that at any point in a magnetic circuit closed by an armature made of a ferromagnetic metal or a ferromagnetic metal alloy element is switched on, through which the current to be secured flows in whole or in part and whose line cross-section is kept so that when the permissible current strength is exceeded, as a result the occurring Joule heat loses the ferromagnetism. Through the associated If the magnetic circuit is interrupted, the saturation of the force line is depressed so far that that the magnetic force acting on the armature is weaker than that on the armature mechanical force acting in the opposite direction, through which the magnetic force Circuit open and at the same time a break contact switched on in the circuit

is opened. Because the ferromagnetic element is used in the event of an overcurrent strength in the circuit needs a certain time until it is heated to the magnetic transition point, if the circuit breaker has a delayed effect, the delay time increases with the Overcurrent decreases. The delayed action of the circuit breaker is so beneficial the intrinsically harmless overcurrent surges that briefly rise above the fuse current strength, how they z. B. arise when starting electrical machines, affects so detrimental this comes off in the event of a sudden short-circuit current. That is why the use the automatic circuit breaker in most cases only in connection with a short-circuit fuse, z. B. a fuse, possible.

The invention relates to a circuit breaker for the automatic interruption of the ao circuit in the event of overload, in which the advantages of the thermal-ferromagnetic circuit breaker can be used in such a way that at the same time an immediately effective short-circuit protection arises. The automatic circuit breaker according to the invention is characterized by a magnetic main circuit and by a magnetic auxiliary circuit, which of the same, of the to be secured Current flowing through the coil are excited, as well as by a main magnetic circuit associated main anchor and an auxiliary anchor associated with the auxiliary magnetic circuit, which sit as a rotating armature on a common armature shaft and an oppositely directed shaft to this Apply torque, with one lying below a certain overcurrent strength Amperage is the torque exerted by the auxiliary armature and an additional torsion spring and in the case of a current that rises above the specific overcurrent strength, that of the The counter-torque exerted by the main armature predominates, as a result of which the armature shaft is rotated and thus actuated a break contact or a break contact triggering device will. The triggering of the break contact or the break contact triggering device in the case of a longer lasting, over the fuse current strength up to the certain Overcurrent increasing amperage goes in such a way that at least one member of the magnetic auxiliary circuit made of a ferromagnetic material, the ferromaghetism of which is a Function of temperature is, exists, and with the appropriate line cross-section in whole or in part is traversed by the current to be backed up, so that at-one over the fuse current strength increasing current strength due to the occurring Joule heat its ferromagnetism loses, with the torque exerted by the auxiliary armature on the armature shaft in whole or in part is omitted and thus the armature shaft through the now predominant one exerted by the main armature Counter-torque is given a rotation leading to the interruption of the circuit.

The advantage of the circuit breaker according to the invention is that the delayed Effect of the same at a current strength below a certain overcurrent strength Short-term overcurrent surges that increase up to the specific overcurrent strength are not taken into account while at a current strength that increases beyond the certain overcurrent strength an immediate interruption of the circuit is brought about.

By correspondingly changing the tension of the torsion spring acting on the armature shaft as well by changing the air gap between the poles of the auxiliary magnetic circuit and the Auxiliary anchor, d. H. by changing the through the torsion spring and through the auxiliary anchor on the Armature shaft exerted torque, the circuit breaker is on a certain overcurrent strength adjustable, which leads to an immediate interruption of the circuit. the The automatic circuit breaker is calibrated to a certain fuse current strength by means of a corresponding Change in the heating characteristics of the ferromagnetic members of the auxiliary magnetic circuit, e.g. B. by changing the line cross-section of the same.

Further details and advantages of the invention are evident from the following description and from can be seen in the drawings. These represent two exemplary embodiments, namely FIG

Fig. Ι a particularly suitable for direct current Circuit breaker in a schematic representation,

2 a circuit breaker intended for alternating current in a schematic representation,

3 shows the diagrammatic representation of the automatic circuit breaker according to FIG. 2, with it removed Insulating hood and partially cut-open insulating base,

4 shows the individual representation of the switch-off contact designed as a double contact,

Fig. S shows the individual representation of the contact release arm Locking device that secures its release position and is connected to a closing magnet,

6 shows the armature shaft and the common switching shaft of two automatic circuit breakers, which are combined to form a fuse unit controlling a common switch-off contact,

7 shows the diagrammatic representation of the automatic circuit breaker provided with its insulating cover, from which the arrangement of the electrical connections and the type of fastening of the insulating base it appears

8 the screw serving as a stop for the main anchor in a special design.

The one shown schematically in FIG. 1 and schematically and graphically in FIGS. 2 and 3 Circuit breaker has a main magnetic circuit and an auxiliary magnetic circuit as well one main armature 1 associated with the main magnetic circuit and one with the magnetic one Auxiliary circle associated auxiliary anchor 2. Of the

The main magnetic circuit, which is closed by the main armature, is controlled by an electromagnet 3 caused, which is excited by a coil 4 through which the current to be secured flows. Of the Electromagnet 3 has two branch legs 5 acting as auxiliary poles on auxiliary armature 2, which in the also caused by the electromagnet 3 and by the auxiliary armature 2 closed magnetic auxiliary circuit form intermediate links. The one against the electromagnet 3 electrically isolated intermediate legs 5 are made of a ferromagnetic alloy, whose ferromagnetism is a function of temperature. The branch legs are through an example made of silver band 6 conductively connected and are of the to be secured Electricity flowed through in whole or in part. By dimensioning the cable cross-section accordingly the branch leg is achieved that with a sustained increase over the fuse current strength Overcurrent strength the branch legs are heated by the occurring Joule heat to the magnetic transition point and thus lose their magnetic properties.

A partial flow of the current to be secured through the branch legs 5 is, as shown in Fig. 1, achieved by arranging a resistor 7 connected in parallel.

In the circuit breaker according to FIGS. 2 and 3 intended exclusively for alternating current the heating current for the branch legs 5 is supplied by the secondary winding 8 of a transformer, the primary winding of which is formed by the exciter coil 4 for the electromagnet 3. the Branch legs 5 are thus traversed by a current, the strength of which depends on the current to be secured.

The main anchor 1 and the auxiliary anchor 2 are designed as rotating anchors, on a common

* o Armature shaft 9 arranged, which in the the pole ends of the electromagnet 3 connecting, consisting of non-conductive material end shields 10 and 11 are rotatably mounted. The arrangement of the main anchor 1 and the auxiliary anchor 2 is such

♦ 5 struck that when the circuit is closed, this creates an oppositely directed torque is exerted on the armature shaft 9. If the overcurrent is below a certain level Amperage is through the auxiliary armature 2 and an additional torsion spring 12 on the Armature shaft 9 exerted a torque which is stronger than that by the main armature on the Counter torque exerted by the armature shaft. The armature shaft is moved up to the stop of the main armature r so "twisted against a stop screw 13 that between the pole ends of the Electromagnet 3 and the ends of the main armature ι a large one and between the branch legs 5 and the ends of the auxiliary anchor 2 sets a small air gap.

The torsion spring 12 is in the form of a,. Formed spiral spring and with one end to the auxiliary anchor 2 and with the other end connected to the end shield 10. The connection of the torsion spring 12 to the end shield 10 is taken so that the spring tension can be changed. With a longer lasting, between the fuse current strength and the specific overcurrent strength lying amperage the branch legs 5 by the Joule heat occurring in these up to the magnetic transition point heated so that they lose their ferromagnetism. The associated the failure of the torque 'exerted on the armature shaft 9 by the auxiliary armature 2 is, the torque exerted by the main armature 1 on the armature shaft 9 now predominates which as a result rotates the armature shaft 9 and thus at the same time by one on the armature shaft 9 provided trigger arm 14 a break contact is opened. When the amperage increases The main armature 1 acts on the armature shaft via the specific overcurrent strength The torque exerted is greater than that of the HiHs anchor and the torsion spring 12 applied counter-torque. The associated rotation of the armature shaft 9 is a causes immediate interruption of the circuit.

By changing the torque, which ^ by the auxiliary armature 2 and, by the torsion spring 12 is exerted on the armature shaft 9, the automatic circuit breaker is on the certain overcurrent strength adjustable. The setting of the circuit breaker to the specific overcurrent strength takes place either by changing the tension of the torsion spring 12 or by changing the air gap between the branch legs 5 of the electromagnet 3 and the auxiliary anchor ends. The one Certain overcurrent strength causing immediate interruption of the circuit becomes so high chosen so that the brief overcurrent surges occurring during operation, which are harmless in themselves lie under this. Due to the delayed action of the circuit breaker in the event of an under the specific overcurrent strength, long-lasting overcurrent strength, the short-term, Overcurrent surges up to the certain overcurrent strength are not taken into account.

The automatic circuit breaker is calibrated to the fuse current strength using the appropriate Change in the heating characteristics of the ferromagnetic branch legs 5, specifically by dimensioning the line cross-section accordingly the same. The release arm 14 seated on the armature shaft 9 has a release pin 15 through which in the event of a rotation of the armature shaft 9 caused by the overcurrent strength either, as shown in FIG. 1, a single tongue contact or a double contact according to FIG. 4 in its interrupted position is controlled.

The control of the simple tongue contact in its interruption position goes in the way in front of him that the resilient contact tongue 16 through the release pin 15 of the mating contact tongue 17 is pulled.

In Fig. 4, a removed from the circuit breaker double contact is shown, which from there is a combination between tongue contact and claw contact. The combined Tongue and claw contact is housed in "an insulating housing 18, which by two Screws 19 is attached to the end shield 11. The combined tongue and claw contact points a rigid contact tab 20 and a resilient contact tab 21. The latter is with the power supply and the rigid contact tab 20 is connected to the power line. The conductive connection between the resilient contact tab 21 and the rigid contact tab 20 is connected to the resilient contact tab 21 once by a and with its free end against the rigid contact lug resilient contact tongue 22 and pivotable once by one .on an axis 23. mounted angle lever made, which under the effect of a tension spring acting on this "2S with its rigid arm 26 in a provided on the rigid contact tab 20 resilient Contact claw 27 engages and its resilient arm 28 against resilient contact tongue 22 springs. During the rotation of the armature shaft 9 caused by the strength of the overcurrent by the provided on the release lever 14, acting against the rigid arm 26 of the angle lever Release pin 15 of the rigid arm 26 of the angle lever released from the contact claw 27 and after Once this has been resolved, the resilient contact tongue 22 by the resilient angle lever arm 28 is pressed from its contact position by the rigid contact lug 20.

The release arm 14 is in its release position locked by an automatic locking device according to FIG. the Locking device consists of a pivoted angle lever on which Arm 29 engages a tension spring 30. The arrangement of the angle lever is made such that the Angle lever arm 31 is pivoted away from it when the release arm is controlled into its release position is and under the action of the tension spring in front of the befxrfdlichen in its release position Trigger arm strikes.

. The purpose of a switch-on device connected to the locking device is that the trigger arm is released from the locking device. The switch-on device consists of a solenoid-32 in which an armature 33 designed as a piston is longitudinally displaceable is stored. The armature 33 is connected to the arm 29. of the bell crank in the "way connected that this with a current flow .through the coil through the armature pull from its locking position is pivoted.

Due to the special design of the armature shaft 9, two or more automatic circuit breakers can be closed a fuse unit controlling a common switch-off contact can be combined. In Fig. 6 shows the armature shafts of two automatic circuit breakers, which with the help of a common together control shaft to form a common switch-off contact controlling fuse unit are. The special design of the armature shaft is that it is a hollow shaft and provided at one end with a driver arm 34 in place of the trigger arm 14 is. The common one provided at one end with the release arm 14 for the switch-off contact Switching shaft consists of rotatably mounted in the armature shafts and coupled between the circuit breakers by a coupling member 35 Partial waves 36 together. The actuation of the switching shaft by the individual circuit breakers takes place through the driver arm 34 on the armature shaft 9, the one circuit breaker associated driver arm on one provided on the disk-shaped coupling member 35 Driving pin 37 and the other circuit breaker associated with one on the trigger arm 14 provided driving pin 38 acts.

7 shows the automatic circuit breaker provided with an insulating hood 39. The insulating hood 39 is 8g attached by two screws 40 to an insulating base 41, which serves as a carrier for all parts of the circuit breaker is used. The fastening of the latter on any fastening surface, z. B. on a switchboard, is carried out by provided on the mounting surface and with a through-hole provided mounting bracket 42 and by socket pin 43, of which z. B. each inserted through two mounting brackets 42 and through one of the holes in the insulating base 41 will.

In Fig. 8, the stop screw 13 for the main anchor 1 is shown in a special version. This also serves to absorb shock. Here the stop screw is on front end provided with a cavity in which one on the one hand by a Bördeirand45 held and on the other hand against a shock-absorbing pad 46 pending ball 47 is mounted.

Claims (13)

Patent claims: i. Circuit breaker for the automatic interruption of an electrical circuit in the event of overload, characterized by a main magnetic circuit and a magnetic circuit Auxiliary circuit, which is from the same coil (4) through which the current to be protected flows are excited, as well as by a main armature belonging to the main magnetic circuit (1) and an auxiliary armature (2) belonging to the auxiliary magnetic circuit, acting as a rotating armature sit on a common armature shaft (9) and on this an oppositely directed Apply torque, with one lying below a certain overcurrent strength Current strength exerted by the auxiliary armature (2) and an additional torsion spring (12) Torque and one over the certain overcurrent increasing amperage that of the. Main anchor (i) exercised Torque predominates, through which as a result the armature shaft (9) rotates and thus a release arm (14) located on the armature shaft causes a break contact or a break contact release device is actuated. 2. Circuit breaker according to claim 1, characterized characterized in that at least one link (5) the auxiliary magnetic circuit made of a ferromagnetic material, its ferromagnetism is a function of the temperature, and with the appropriate line cross-section »5 cut in whole or in part from what is to be backed up Current flows through it, so that it rises at one over the fuse current strength- ' the and sustained overcurrent strength due to the Joule heat occurring their ferro- ao loses magnetism, which is exerted on the armature shaft (9) by the auxiliary armature (2) Torque completely or partially omitted and thus the armature shaft (9) through the the main armature (1) exerted, now predominant counter-torque a for the interruption rotation leading to the circuit is granted. 3. Circuit breaker according to claims 1 and 2, characterized by a together with the main armature (1) forming the main magnetic circuit U-shaped electromagnet (3), which is excited by a coil (4) through which the current to be protected flows. 4. Circuit breaker according to claims 1 to 3, characterized in that the U-shaped Electromagnet (3) with two acting as auxiliary poles on the auxiliary armature (2) Branch legs (5) is provided that this together with the auxiliary anchor (2) at the same time forms the magnetic auxiliary circuit. 5. Circuit breaker according to claims 1 to 3, characterized in that at least one of the branch legs (5) consists of a ferromagnetic Substance exists and against the Electromagnet (3) electrically isolated, with the current to be secured flowing through it in whole or in part is. 6. Circuit breaker according to claims 1 to 5, characterized in that with alternating current the heating current for the ferromagnetic member (5) or for the ferromagnetic members of the auxiliary magnetic circuit supplied by the secondary winding (8) of a transformer whose primary winding is formed by the excitation coil (4) of the electromagnet (3). 7. Circuit breaker according to claims 1 to 6, characterized in that two or several circuit breakers to a common switch-off contact or a common one Switch-off contact tripping device 6α actuating fuse unit are summarized. 8. Circuit breaker according to claims ι to 7, characterized in that the actuation of the switch-off contact or the switch-off contact tripping device by a common shift shaft takes place, which is rotatable in the hollow shaft-shaped armature shafts (9) stored and between the circuit breakers by coupling links (35) interconnected partial shafts (36) is composed. 9. Circuit breaker according to claims 1 to 8, characterized in that the actuation the switching shaft through the individual automatic screening machines by means of one at one end the "armature shaft (9) provided driver arm (34) takes place, which on one to the Disk-shaped coupling members (35) arranged driving pins (37) acts. 10. Circuit breaker according to claims 1 to 9, characterized in that from the armature shaft of the last automatic circuit breaker protruding end of the switching shaft a release arm (14) for the break contact or for the break contact tripping device sits, which one with the Driver arm (34) interacting on the armature shaft (9) of the last automatic circuit breaker Has driving pin (38). 11. Circuit breaker according to claims 1 to 10, characterized in that the on the armature shaft (9) or on the switching shaft Seated release arm (34) for the switch-off contact or for the switch-off contact tripping device in its release position by an automatic locking device (29, 30, 31) is secured. 12. Circuit breaker according to claims 1 to 11, characterized in that a switch-on device connected to the blocking device (29, 30, 31), e.g. a switch-on magnet (3 ² > 33) is provided for closing the interrupted circuit, which acts on the blocking device in such a way that the release arm (14) is released by this. 13. Circuit breaker according to claims 1 to 12, characterized in that the release arm has two switch-off contacts connected in parallel be operated in such a way that the first contact opens before the second and the second contact is closed before the first. Referred publications: Austrian patent specification No. 99 881. 1 sheet of drawings 1 509 706 5.56