DE4202122C2 - Tripping device for switching devices - Google Patents

Description

The invention relates to a triggering device for switching devices according to the preamble of claim 1.

Tripping devices for switching devices, such as Circuit breaker or motor protection switch, consisting of one Bimetal strips, for overcurrent release and one Quick release device or short-circuit release, the one Magnet yoke, a magnetic armature acting on the switch lock and has a current-carrying excitation winding.

Because of the high currents that occur in the event of a short circuit and the associated high forces between magnetic armature and Magnet yoke it is known and often sufficient that in one Direction of current through the bimetal strip through the Pass the magnetic yoke and this current as excitation for to use the electromagnetic quick release, so one half turn as excitation.

It is also known to use a parallel bimetallic strip Resistance, or shunt, to pass through the magnetic yoke and at the same time as excitation for the short-circuit release use, the current through stranded wire at the end points of the Bimetal is led out. This has the advantage that the structure is very simple, d. H. there will be no additional Excitation winding needed.

A disadvantage is the limited trigger sensitivity, the due to the low number of turns. The disadvantage is also that the stranded wire moves with the bending of the bimetal becomes.

From US 39 59 754 (there Fig. 2) it is known to use a conductor wound around the magnetic yoke as a separate coil connected in series to increase the sensitivity of the short circuit or quick release.

However, the arrangement of a separate coil is expensive mount and often for reasons of space in the switchgear difficult to accommodate because the dimensions of the switchgear in Ratio to their switching capacity are getting smaller.

To the disadvantage of limited trigger sensitivity avoid it is also known to pass the magnetic yoke through a Wrapping stranded wire several times, as in EP 0 309 383 A1 is shown and described. The advantage here is that there is no need to use winding machines because a slight flexibility is given by hand. Also will the effort required to manufacture coils decreased.

In contrast, with high production numbers is an automated one Manufacturing advantageous, which is not possible.

With this solution there is also an insulating hose for the Strand required.

From DE-PS 9 46 826 is a triggering device of the type mentioned known. This creates a U-shaped bimetal used. The magnetic yoke surrounds you Leg of the bimetal. The other leg of the bimetal is passed outside this magnetic yoke. Another magnetic yoke surrounds this leg. The passed legs to increase the magnetic Flooding at which the trigger sensitivity of the Short-circuit release improved. An additional turn made of flat material is also led through the magnetic yokes and the bimetal electrically connected in series.

A bimetal, which is also U-shaped, is still made of DE-PS 8 75 063 known.

A bimetal that has become known from US Pat. No. 2,629,796 (there FIG. 2) has a likewise U-shaped electrical resistance, which is connected in parallel with the bimetal, that is to say a shunt. This has the advantage that a bimetal in the thermal release can be used for different release areas by causing a weakening of the current flow in the bimetal. The different trigger areas can be reached by changing the electrical resistance of the shunt. The connection of the bimetal and the shunt as well as the assembly in the switching device is conceivable with this arrangement as automated production.

Further measures to increase the trigger sensitivity the quick release are not provided here.

The object of the invention is therefore in a Tripping device for switching devices according to the preamble of Claim 1 measures to take on the one hand To weaken the current in the bimetal, so that the same bimetal for different trigger areas of the thermal trigger can be used and on the other hand an increase in the sensitivity of the short-circuit release to achieve without the need for separate coils, the Tripping device should be simple to build and manufacture and especially for automated high manufacturing Quantities should be suitable.

The object of the invention is characterized by the Features of claim 1 solved, while in claims 2 to 14 particularly advantageous developments of the invention Marked are.

The invention then has the advantage that only one element or shunt both for weakening the current in the bimetal thermal trigger as well as to increase the trigger sensitivity the short-circuit release is provided that this shunt simple can be assembled and automated production possible is. Additional coils are not required.

The features of claims 2 to 4 result advantageous designs of the shunt.  

A simple manufacture of the magnetic yoke, while inexpensive magnetic properties are obtained from the Features of claims 5 to 9.

It is particularly advantageous if the magnetic armature according to the Features of claims 10 to 14 is executed because both particularly favorable magnetic properties as well as good ones mechanical properties with simpler and cheaper Manufacturing are present.

Based on the drawing, in which a way to carry out the invention is shown a release device with U-shaped bimetals, the invention with a wound shunt and other embodiments of Invention described and explained in more detail become.

It shows

Fig. 1 is a perspective view of an over-current and instantaneous release which does not contain all features of the invention,

Fig. 2 is an illustration of the bimetal,

Fig. 3 is a side view of the quick-release shown in FIG. 1,

Fig. 4 is a representation of the instantaneous release of FIG. 1 from above,

Fig. 5 illustrates the processing of a part of the magnetic yoke,

Fig. 6 is a perspective view of the, in Fig. 5 the part shown, after bending

Fig. 7 shows the processing of another part of the magnetic yoke,

Fig. 8 is a perspective view of the part shown in Fig. 7, after bending,

Fig. 9 is a development of the magnet armature,

Fig. 10 is a perspective view of the magnet armature,

Fig. 11 is a perspective view of the shunt according to the invention for a high triggering sensitivity and

FIG. 12 shows the shunt shown in FIG. 11 in the triggering device.

In FIG. 1, the triggering device consisting shown for an overcurrent release and a quick release for a three-phase switching device.

Part of the tripping current flows directly in the material of a bimetal 2 , which has an approximately U-shaped shape. The other part flows through a likewise U-shaped electrical resistor or shunt 3 connected in parallel with the bimetal 2 .

In the event of an overcurrent, the bimetal 2 heats up and deforms in such a way that it actuates a release bridge which is operatively connected to the switch lock (not shown) and opens the switch contacts.

The quick release consists of a U-shaped magnet yoke 5 and a magnet armature 6 , which also engages a release bridge 28 .

The magnet armature 6 is designed as a hinged armature, the bearing point being arranged on the bottom and integrated in the magnet yoke 5 and the magnet armature 6 .

In the event of a high fault current, for example a short circuit, the magnet armature 6 is folded against the tension spring 18 to the magnet yoke 5 . The trigger flag 20 is arranged at the end opposite the axis of rotation and at approximately the same height as the trigger flag of the bimetal 2 .

The magnetic field is generated by the current-carrying bimetal 2 and the shunt 3 . The magnetic yoke 5 encloses both a leg 7 of the bimetal 2 and a leg 8 of the shunt 3 .

The other legs 9 and 10 of the bimetal 2 and the shunt 3 also contribute to increasing the magnetic flux. Bimetal 2 , or bimetal 2 and shunt 3 , therefore act like an excitation coil.

The electrical connection between the busbars 11 and 12 takes place through the U-shaped bimetal 2 , the current flow being identified by the current arrows i in FIG. 2.

The setting of the trigger sensitivity of the quick release is achieved by means of a setting button 14 with an eccentrically arranged pin which, when rotated, shifts the trigger bridge in the direction of the arrow X ( FIG. 1). The air gap between the magnet armature 6 and the magnet yoke 5 , which determines the trigger sensitivity, is therefore changed here.

The magnetic yoke 5 consists of two parts 5 a and 5 b, which are shown in FIGS. 5 to 8.

Both parts 5 a and 5 b are produced by stamping and bending as individual parts and then assembled into a magnetic yoke 5 .

Both parts 5 a and 5 b have U-shaped areas, both parts being assembled at their U areas, such that part 5 a engages around part 5 b.

The fact that the sheets of parts 5 a and 5 b, in contrast to the production from a sheet, only half the material thickness, these are particularly easy to punch. The bending radii can also be made smaller than if the magnetic yoke 5 were made from one part.

If a magnetic sheet is used for the material thickness too processed small radii, then cracking occurs Causes interference.

The U-regions guiding the magnetic flux can be provided with further stacked U-shaped parts in order to further reduce the magnetic resistance. However, thinner parts 5 a and 5 b can also be used in order to achieve the desired magnetic flooding by combination with further U-shaped parts, depending on the triggering range of the quick release.

Functions are assigned to the individual parts 5 a and 5 b, all of which can hardly be realized with just a single sheet, so the first part 5 a has webs 15 for fixing in the housing. The second part 5 b, however, has an integrated bearing 16 for the magnet armature 6 .

Furthermore, the second part 5 b has an L-shaped arm 17 which is provided for holding a tension spring which acts on the armature 6 .

For these functions, or function recordings, none other parts or sections in the housing of the switchgear needed, such as bearings for the spring of the magnet armature and Bearings for the magnetic armature itself, so that a Component savings occurs.

In addition to making assembly and production easier, the use of two parts 5 a and 5 b improves tolerance.

By using two parts, the pole faces in can easily be enlarged, resulting in an increased magnetic force has the consequence.

The magnetic yoke can thus be constructed modularly, such that the magnetic sheets or parts 5 a and 5 b contain one or a maximum of two mechanical holding elements. This considerably simplifies production.

Under a mechanical holding element is z. B. to understand the inclusion of a spring, the mounting of the magnet armature 6 or the mounting of the magnet yoke 5 .

The magnet armature 6 is folded from a single magnet sheet and folded over in such a way that a region 19 of the magnet armature has a thickening, that is to say it is folded up.

As can be seen in FIG. 9, the magnetic sheet has two diagonally offset sections 21 and 22 , the upper section 21 leading the release flag 20 acting on a release bridge 28 and the lower section 22 having webs 23 , the bearing point form for the magnet armature.

In section 22 there are also holes 24 for fastening the tension spring 18 .

After folding, both sections 21 and 22 are directly below one another, as can be seen in FIG. 10 .

The thickening of the area 19 improves the magnetic properties without the need for additional parts. The thickening of the area 19 thus increases the magnetic field due to the higher flow. Furthermore, saturation limits are shifted without the need for additional parts, which mean increased manufacturing, assembly and cost expenditure.

Another advantage is the lower mass of the sections 21 and 22 , which reduces the moment of inertia of the armature 6 . A further reduction in the moment of inertia and improvement in the magnetic properties is achieved by subsequently pressing down the sections 21 and 22 , the original shape being achieved by subsequent punching. The reduction in mass in these sections 21 and 22 further improves the moment of inertia of the magnet armature and reduces the leakage flux.

Due to the lower mass, the counterforce of the spring can be used for the shock resistance is important.

As can be seen in FIG. 1, the thickening is only present in the area of the magnetic yoke 5 , namely with a height H which corresponds to the height H of the magnetic yoke and which is identified in FIGS . 5 and 9.

In addition, the area 19 can be further increased in thickness by multiple folding, which further improves the magnetic properties.

A high trigger sensitivity for the quick release is often required, which cannot be achieved with the U-shaped bimetal and a U-shaped shunt alone. Referring to FIG. 11 u. 12, the U-shaped shunt 3 is replaced by a screw-shaped, made of enamelled wire shunt 25 , which serves as a coil for increasing the magnetic field due to its turns that are bent several times around the magnetic yoke.

The shunt 25 is electrically connected in parallel with the bimetal 2 , the outer connecting leg 26 of the shunt 25 being connected to the flat side of the bimetal 2 , as indicated in FIG. 2 by reference numeral 27 , and the inner connecting leg 29 on the narrow side of the leg 9 of the bimetal 2 and between the two legs 7 and 9 is connected.

This is a simple way to increase the flow achieved without the need for separate coils or the like are.

A shunt is to be understood here as a resistance element with a defined resistance value, which is connected in parallel to the bimetal. Like the shunt 3 in FIG. 1, this shunt 25 has the task of achieving a current distribution or a weakening of the current flow in the bimetal, as a result of which only one embodiment of the bimetal is required for different triggering regions of the thermal trigger. The resistance value of the shunt is therefore adapted to the tripping range.

The shunt 25 simulates the required electrical resistance, which is required for the current distribution, firstly by the material used or conductivity of the material or also by the length or number of turns.

Claims (14)

1.Tripping device for switching devices with a thermal overcurrent release, which has at least one bimetal, the triggering device having an electromagnetic quick release, consisting of at least one magnetic yoke and at least one magnet armature, the current flowing through the bimetal being used to generate a magnetic field for quick release to produce, furthermore the bimetal is U-shaped, the magnetic yoke encloses one leg of the bimetal and the other leg of the bimetal is guided outside this magnetic yoke, characterized in that
that a shunt ( 25 ) wrapped around the magnetic yoke ( 5 ) is electrically connected in parallel with the bimetal ( 2 ),
that the shunt ( 25 ) consists of an insulated conductor with a resistance value adapted to the triggering range of the thermal release, that the shunt ( 25 ) is wound several times around the magnetic yoke ( 5 ) and that the shunt ( 25 ) is wound in a spiral or helical shape. 2. Tripping device according to claim 1, characterized in that the shunt ( 25 ) consists of enamelled wire. 3. Tripping device according to one of the preceding claims, characterized in that the outer connecting leg ( 26 ) of the shunt ( 25 ) is connected to the flat side of the bimetal ( 2 ) and the inner connecting leg ( 28 ) on the narrow side of the leg ( 9 ) of the Bimetal ( 2 ) between the two legs ( 7 and 9 ) is connected. 4. Tripping device according to one of the preceding claims, characterized in that the insulated conductor of the shunt ( 25 ) has a rectangular cross section. 5. Tripping device according to one of the preceding claims, characterized in that the magnetic yoke ( 5 ) consists of at least two magnetic sheets or parts ( 5 a and 5 b). 6. Tripping device according to claim 5, characterized in that the magnetic sheets for the magnetic yoke ( 5 ) are assigned a maximum of two mechanical holding elements per magnetic sheet. 7. Tripping device according to claim 5 or 6, characterized in that the first part ( 5 a) webs ( 15 ) for fixing and storage in the housing of the switching device. 8. Tripping device according to one of claims 5 to 7, characterized in that the second part ( 5 b) has an L-shaped arm ( 17 ) for holding a tension spring ( 18 ) which cooperates with the magnet armature ( 6 ). 9. Tripping device according to one of claims 5 to 8, characterized in that the second part ( 5 b) has bearing points ( 16 ) for the magnet armature ( 6 ). 10. Tripping device according to one of the preceding claims, characterized in that the magnet armature ( 6 ) is made from a single magnetic sheet, such that a thickening of the magnet armature ( 6 ) occurs in the region of the magnet yoke ( 5 ) by folding. 11. Tripping device according to claim 10, characterized in that the unfolded magnetic sheet has two diagonally offset sections ( 21 and 22 ), the upper section ( 21 ) leading the release tab ( 20 ) and the lower section ( 22 ) webs ( 23 ), which form bearing points for the magnet armature ( 6 ). 12. Tripping device according to claim 11, characterized in that holes ( 24 ) for fastening the tension spring ( 18 ) are present. 13. Tripping device according to claim 11 or 12, characterized in that the outside of the magnetic yoke ( 5 ) located sections ( 21 and 22 ) are subjected to a reduction in material by embossing to a smaller thickness and subsequent punching. 14. Tripping device according to one of the preceding claims, characterized in that the bimetals ( 2 ) of the individual phases are arranged in parallel on their flat sides.