ES2428495T3 - Electrical protection device comprising the differential protection function - Google Patents

Abstract

The apparatus e.g. bipolar modular differential circuit breaker (A), has phase and neutral disconnecting modules (1, 2) and a differential protection module (B) mounted on a rail. A core (6) is positioned within the protection module such that a center part of a coil is located between an axial plane of the core parallel to an initial direction of movement of electric arc and passing via a separation point of main contacts of one of the disconnecting modules, and another axial plane of the core located at 45 degrees with respect to the former plane from a side of a disconnecting chamber.

Description

Electrical protection device comprising the differential protection function

The present invention relates to an electrical protection apparatus comprising the differential protection function, said electrical apparatus comprising at least one phase and / or neutral cutting device and a differential protection device, said devices being laterally juxtaposed. and mounted on the same mounting bracket as a rail, each cutting device comprising two main contacts, said main contacts being closed in normal operation of the apparatus and being adapted to open in such a way that the current is interrupted in the event of an incident in an electrical circuit, and a cutting chamber towards which the arc travels from the moment the contacts are separated, said differential protection device comprising a toroid that extends in a plane that extends substantially perpendicular to the alignment direction of the devices, being the axis of the hole of the toroid to the axis of alignment of the devices, said toroid being destined to receive a certain number of so-called primary windings and a winding called secondary of measurement of the fault current, the number of primary windings corresponding to the number of devices of electrical cut, forming the

15 primary windings by winding around the toroid of primary conductors that each connect an output terminal of a cutting device with a contact area of the differential protection device.

Differential circuit breakers are known which comprise, in a manner known per se, a circuit breaker associated with a differential protection module. The circuit breaker is an electromagnetic or electronic protection device whose function is to interrupt the electric current in case of an incident in an electrical circuit by opening the

20 main contacts of said circuit breaker. You can interrupt an overload current thanks to thermal trip means and a short circuit current thanks to magnetic trip means.

The differential protection module is adapted to guarantee the protection of people, guaranteeing a trip in case of abnormal current leakage. This differential protection module comprises a toroid-shaped magnetic circuit on which one or several phase and neutral circuits, called

25 primary circuits, as well as a circuit called secondary that constitutes a coil for detecting the fault current.

In the absence of leakage or residual fault current, the flows produced by the coils of the primary circuit are canceled, nothing happens. If a fault occurs, the residual fault current produces an imbalance of the flows in the coils of the primary circuit and a magnetic flux appears in the toroid. The measuring coil is the focus of

30 an electro-magnetic energy that feeds an electromagnet causing the circuit breaker to unlock and the opening of its main contacts.

From the moment the contacts separate, the arc moves towards the cutting chamber due to the effect of the so-called Laplace force, induced by the geometry of the fixed and mobile contacts. During the path between the contacts and the camera, the arc is channeled between two faces that allow you to increase your travel speed,

35 guide your path and lengthen.

In certain cases, the toroid is located just in front of the cutting chamber. The toroid is provided with primary coils that are wound on its circumference and the lateral proximity of these coils influences at the same time the opening torque of the mobile contact (direction, direction, point of application, influence of the environment) and on the propulsion force of the electric arc since it is generated and during its looping

40 just before the displacement of the arch to the prechamber.

From this it follows that the arc hesitates and stagnates, and consequently, an increase in thermal stress occurs. Thus, in order to obtain the desired cutting yields, it would be useful to oversize the poles.

An artifice, to cancel out the negative effect produced by the windings of the toroid, could be to add a metal screen between the toroid and the circuit breaker. But, given the insufficient space to accommodate a

45 metal screen with a significant thickness (at least 2 mm thick), this solution is not viable to cancel the negative effects of the primary coils. Finally, the cost of manufacturing and handling an additional part is not feasible in an industrial context. An electrical protection apparatus of this type is known from EP 0 665 569 A1.

The present invention aims to improve the cut and prevent destruction of the circuit breaker pole that joins the differential protection block during short circuits.

For this purpose, the present invention aims at an electrical protection apparatus, this apparatus being characterized in that if an observation direction is defined defined by the three successive planes that extend substantially perpendicular to the toroid plane and to the fixing plane of the apparatus, said planes comprising respectively the mobile contact (s), the fixed contact (s) and the cutting chamber 55, the winding (s) on The toroid follows (n) the winding rule that consists of the primary conductor coming from the output terminal electrically connected to the fixed contact of the cutting device called first, located as close as possible to the differential protection device, is wound around the toroid counterclockwise, while the primary conductor from the output terminal electrically connected to the fixed contact of the cutting device second nominee located next to the cutting device called first, on the side opposite to the differential protection device, is wrapped around the toroid, clockwise, and the hole of the toroid is located in front of the blade that 5 separates the cutting device called first from the differential protection device, and in front of the cutting chamber intended to receive the electric arc, said winding directions are inverted around the toroid if the output terminal (s) is (n) ) electrically connected to the mobile conductor (s), and the toroid is located inside the differential protection device such that the center of the first winding is between an axial plane of the toroid said foreground being substantially parallel to the

10 initial direction of travel of the arc and passing through the point Y of separation of the main contacts of at least one of the cutting devices, and an axial plane, called second, of the toroid, located at 45 ° with respect to this first plane in The side of the cutting chamber.

Thus, if the output terminal is connected to the mobile contact instead of the fixed contact, then the corresponding winding directions are reversed.

15 According to a particular embodiment, the apparatus is a modular apparatus, each cutting device and the differential protection device being disposed each within a module separable or not from the other modules.

According to a particular feature, the toroid is located inside the differential protection device, such that the axis of the toroid extends substantially parallel to the direction of alignment of the modules.

20 According to another characteristic, the separation points of the main contacts, associated respectively with the different cutting devices, are located in said plane called first.

According to another characteristic, the number of electric cutting devices is two and comprises a phase cutting device and a neutral cutting device.

According to another characteristic, the number of electric cutting modules is two and comprises a phase cutting module and a neutral cutting module.

According to another characteristic, the axis of the toroid is substantially perpendicular to the side walls of the modules.

According to another characteristic, said apparatus comprises at least two windings connected respectively to two cutting devices, this apparatus is characterized in that the center of the second winding is located on the side opposite to the center of the first winding with respect to the axis of the toroid, thereby that these two windings are

30 angularly displaced by 180º with respect to each other, with respect to this axis.

According to another characteristic, the center of the measuring winding is located in an axial plane of the toroid located approximately 45 ° with respect to the axial plane called first containing the center of the first winding.

The differential protection device is located to the left or to the right of the one-phase and / or neutral cutting device, the above-mentioned winding rule being applied in the same way in both

35 arrangements mentioned if the output terminals are electrically connected to the same contacts.

According to another characteristic, the apparatus is a differential circuit breaker, comprising at least one cutting and / or neutral device, and a differential protection device.

According to another characteristic, the apparatus is a modular bipolar differential circuit breaker.

Other advantages and features of the invention will be better shown in the detailed description given below and refers to the attached drawings given by way of example only, in which:

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Figure 1 is a perspective view, schematically illustrating a circuit breaker associated with a differential protection module according to the prior art;

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Figure 2 is a perspective view, which schematically illustrates two cutting modules respectively phase and neutral associated with a differential protection module, also according to the prior art, during cutting;

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Figure 3 is a view similar to Figure 1, illustrating a circuit breaker associated with a difference protection module according to a particular embodiment of the invention;

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Figure 4 is a view similar to Figures 1 and 3, illustrating a circuit breaker associated with a differential protection module according to another embodiment of the invention;

Figure 5 is a view similar to Figure 2, according to another embodiment of the invention, during cutting;

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Figure 6 is a partial view, which illustrates following a plane parallel to the depth of the apparatus, the cutting chamber, the main contacts, the toroid and its windings; Y

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Figure 7 is a graphical representation illustrating in ordinates, the opening torque in (N.M) of the mobile contact as a function of the angular position in degrees of one of the coils around the axis of the toroid.

5 In Figures 1, 3 and 4, a bipolar circuit breaker A can be seen coupled by a 3 of its side faces to a differential protection module B, the assembly being mounted on the same mounting bracket (not shown). This circuit breaker comprises two modules, respectively a phase 1 cutting module called first, and a neutral cutting module 2, called second. The output terminals of circuit breaker A, 10, 11, for the prior art and 14, 15 for the device according to the invention, are electrically connected to terminals 9 of the

10 differential protection apparatus B after passing through a toroid 6 through conductors called primary 7, 8, as regards the prior art and 12, 13; 16, 17; and 18, 19 as regards the invention.

This toroid 6 extends inside the differential protection module following a plane parallel to the side faces 3, 4, 5 of the modules, extending its X axis parallel to the longitudinal direction of the fixing bracket and the alignment direction of the modules

Thus, according to the prior art, as shown in Figures 1 and 2, the conductors referred to as primary 7, 8, one of which is a phase conductor and the other a neutral conductor, are introduced into the inside the toroid 6 on its face 6a located on the side of the circuit breaker A, then turn around the toroid before re-entering the toroid on the same side as before, then the drivers cross the toroid a second time and they return to the side 6b of this opposite to the previous one, after which the

20 conductors are connected to zones 9 of differential module B, said zones 9 being designed to receive the output terminals (not shown) of differential module B.

In this embodiment of the prior art, the primary conductor 8 from the terminal 11 of the circuit breaker A, located on the left in the figures, crosses the toroid 6 in the opposite direction to the clockwise, while the primary conductor 7 from of terminal 10, located to the right of the first, crosses the toroid in the sense of

25 clockwise.

According to this embodiment, the threads are as short as possible and comprise a minimum of folds. The wires do not cross between terminals 10, 11 and the output of toroid 6.

According to the three embodiments of the invention that are illustrated respectively in Figures 3, 4 and 5, the primary conductor 13, 17, 19 from the terminal 15, located in the cutting module called second 12, is wound

30 on the toroid 6 clockwise, while the second conductor 12, 16, 18 from the terminal 14 of the cutting module 1 called first, is wound on the toroid 6 counterclockwise watch. Thus, according to the invention, the direction of rotation around the toroid 6 of the primary conductors has been reversed with respect to the direction of rotation of the corresponding primary conductors of the apparatus according to the prior art.

35 According to the embodiment of the invention illustrated in Figure 3, the primary conductors 12, 13 are introduced inside the toroid through the face 6a of the toroid 6 located on the side of the circuit breaker A, then turn around the toroid, and then go through the toroid again to exit again on the face 6b opposite to the one located on the side of the circuit breaker. Thus, in this embodiment, the wires cross at the exit of the toroid. But it should be noted that these wires could be crossed between terminals 14, 15 and exit 6a of the toroid.

40 According to the embodiment of the invention illustrated in Figure 4, the primary conductors 16, 17 are introduced inside the toroid 6 by its face 6b located on the side opposite the circuit breaker A, then turn around the toroid , and then cross the toroid again to exit it through its face 6a located on the side of the circuit breaker to connect in zones 9 of the differential protection module B. In this embodiment, the wires are bent, but do not cross , between terminals 14, 15 and the output of toroid 6a.

45 According to the embodiment of Figure 5, the primary conductors 18, 19 are introduced into the toroid 6 by the face 6b thereof located on the side opposite the circuit breaker, then cross the toroid 6 and exit through the other side 6a, before to be connected in zones 9 of the differential protection module.

According to the invention and as depicted in Figure 6, the X axis of the toroid is located substantially perpendicular to the cutting chamber C. The first winding 21 is located on the toroid 6 such that its center 22 is located between a first axial plane Q of the toroid 6, which passes through the point Y of separation of the contacts 23, 24 of the circuit breaker, and a second axial plane R of the toroid that forms with the first plane Q an angle α of practically 45 °. The center 26 of the second winding 25 (not shown) is then placed in a diametrically opposite position with respect to the center 22 of the first winding 21, and the measuring winding (not shown) is in a displaced position of the first primary winding 21 and of the second

55 primary winding with an angle of practically 90º. According to this particular embodiment, this first axial plane Q of the toroid is a plane that crosses the apparatus from the nose of the apparatus towards the fixing support and perpendicularly to this support.

Thus, according to the invention, one 21 of the windings has been placed in a precise area in front of the point of separation of the contacts and has been wound in a winding direction that allows to generate a magnetic field which allows both to favor the electromagnetic force acting on the arc and leading it towards the cutting chamber, and also increasing the opening torque of the mobile contact.

5 Advantageously, the face 6a of the toroid located on the side of circuit breaker A is located as close as possible to the separation sheet 3 between the circuit breaker A and the differential protection module B, so as to reduce as much as possible the distance between the contacts and the toroid. In order to take advantage of the environment of the toroid to optimize the channeling of the magnetic field lines, any metallic element (of armor type) that may disturb the magnetic field of the toroid will be removed, and placed between the toroid and the pole of the circuit breaker . In effect, the

10 set of the metal parts as well as the conductors contribute to a complex closure of the magnetic field lines and, in particular, those produced by the winding of the toroid.

Thus, by means of the invention, a modification of the propulsion force on the cutting arc is generated in the direction of its movement towards the cutting chamber from the moment the contacts are opened (at the closing of the arc ), and then during its movement to the pre-chamber and to the cutting chamber.

15 The circuit breaker no longer runs the risk of being destroyed by the negative effects of the winding field of the toroid on the arc during short circuits.

Indeed, if the winding is arranged in the traditional way, as illustrated in Figure 1, the lateral parasitic component L of a factor 2 is increased as illustrated in Figure 2, which has the effect of reducing the component propulsion T.

20 If, on the contrary, a winding according to the invention is carried out, in a reverse direction with respect to the industrial sense, this lateral component L is annulled, and consequently the propulsion component T of the force on the arc towards the arc is increased. cutting chamber, reaching its optimum value for a recommended position corresponding to a maximum angle of 45 ° between the first axial plane R mentioned above, as illustrated in Figure 7 representing a characteristic curve of the gain obtained in the reverse winding according to

Invention, depending on the angle between the two planes mentioned above. Indeed, in this figure, it can be seen that when the winding is arranged on the circumference of the toroid in different angular positions with respect to said first axial plane of the toroid, by 25 ° steps, positive and negative, a curve is obtained that presents a very pronounced peak peak between 0 and 45º.

The same is true for the opening torque that is exerted on the mobile contact that is multiplied by a factor 3 with

30 the reverse winding and a placement of the first coil in the recommended area (angle between 0 and 45 °).

Thus, according to the invention, the environment of the toroid is used to optimize the channeling of the magnetic field lines so that they produce beneficial effects on the electric arc and the moving contact.

35 Moreover, the cut is improved with respect to a solution of a differential block equipped with a shield.

Indeed, the field effects according to the invention improve the cut, while the solution with a screen only restores it. A gain is obtained on the opening torque of the mobile contact of a factor 3 and a cancellation of the lateral parasitic component, then the gain is 100%.

Claims (12)

one.

 Electrical protection apparatus (A) comprising the function of differential protection, said electrical apparatus comprising at least one cutting device and / or neutral (12) and a differential protection device (B), said devices being located laterally juxtaposed and mounted on the same mounting bracket as a rail, each cutting device comprising two main contacts, said main contacts (23, 24) being adapted to be closed in normal operation of the apparatus and adapted to open in such a way that interrupt the current in the event of an incident in an electrical circuit, and a cutting chamber (C) towards which the arc moves from the moment the contacts are separated, said differential protection device comprising a toroid (6) that is extends in a plane that extends substantially perpendicular to the direction of alignment of the devices, the axis being of the toroid orifice parallel to the alignment axis of the devices, said toroid being intended to receive a certain number of so-called primary windings (21) and a winding (25) called secondary of measurement of the fault current, corresponding the number of windings primary to the number of electrical cutting devices, the primary windings being formed by winding around the toroid of primary conductors (18, 19) that each connect an output terminal of a cutting device with a contact zone of the differential protection device , characterized in that if an observation direction defined by the three successive planes that extend substantially perpendicular to the plane of the toroid and the fixing plane of the apparatus is considered, said planes respectively comprising successively the contact (s) ) mobile (s), the fixed contact (s) and the cutting chamber, the bo The winding (s) on the toroid follow the winding rule that consists of the primary conductor (12, 16, 18) coming from the output terminal (14) electrically connected to the fixed contact of the cutting device called first (1), located as close as possible to the differential protection device, it is wound around the toroid (6) in a counterclockwise direction, while the primary conductor (13, 17, 19) from the electrically connected output terminal (15) the fixed contact of the cutting device (2) called second, located next to the cutting device called first, on the side opposite to the differential protection device, is wound around the toroid (6), clockwise , because the hole of the toroid is located in front of the sheet (3) that separates the cutting device called first (1) from the differential protection device B, and in front of the cutting chamber C intended for receiving r the electric arc, said winding directions being inverted around the toroid if the output terminal (s) is electrically connected to the mobile conductor (s), and because the toroid (6) is located inside the differential protection device such that the center (22) of the first winding (21) is between an axial plane Q of the toroid, said first plane being substantially parallel to the initial direction of displacement of the arc and passing through the point Y of separation of the main contacts (23, 24) of at least one of the cutting devices, and an axial plane R, called second, of the toroid, located at 45 ° with respect to this Close-up Q on the side of the cutting chamber.

2.

 Electrical protection apparatus according to claim 1, characterized in that it is a modular apparatus, each cutting device (1, 2) and the differential protection device B each being arranged within a module separable or not from the other modules.

3.

Electrical protection apparatus according to claim 1 or 2, characterized in that the toroid (6) is located inside the differential protection device B, such that the X-axis of the toroid (6) extends substantially parallel to the direction of alignment of the modules.

Four.

Electrical protection apparatus according to any one of claims 1 to 3, characterized in that the separation points Y of the main contacts (23, 24), associated respectively to the different cutting devices (1, 2), are located in said plane First called Q.

5.

Electrical protection apparatus according to any one of the preceding claims, characterized in that the number of electrical cutting devices (1, 2) is two and comprises a phase cutting device and a neutral cutting device.

6.

 Electrical protection apparatus according to any one of claims 2 to 5, characterized in that the number of electrical cutting modules is two and comprises a phase cutting module and a neutral cutting module.

7.

Electrical protection apparatus according to any one of claims 2 to 6, characterized in that the X axis of the toroid (6) is substantially perpendicular to the side walls (3, 4, 5) of the modules.

8.

Electrical protection apparatus according to any one of the preceding claims, comprising at least two windings (21, 25) connected respectively to two cutting devices (1, 2), characterized in that the center (26) of the second winding (25) is located on the side opposite (22) of the first winding (21) with respect to the X axis of the toroid (6), such that the two windings are angularly displaced 180 ° from each other, with respect to this axis.

9.

Electrical protection apparatus according to any one of the preceding claims, characterized in that the center of the measuring winding is located in an axial plane of the toroid located at approximately 45 ° with

with respect to the axial plane called first Q containing the center (22) of the first winding (21).

10.

Electrical protection apparatus according to any one of the preceding claims, characterized in that the differential protection device is located to the right or to the left of the one-phase and / or neutral cutting device, the winding rule mentioned above being applied in the same way in both

5 arrangements already mentioned if the output terminals are electrically connected to the same contacts. 11. Electrical protection apparatus according to any one of the preceding claims, characterized in that it is a differential circuit breaker, comprising at least one cutting and / or neutral device A and a differential protection device B. 12. Electrical protection apparatus according to claim 11, characterized in that it is a modular bipolar differential circuit breaker 10.