FR2867603A1 - DIRECT-INSERT, SWIVEL-BASED GROUND DISCONNECT WITH SINGLE MOVEMENT - Google Patents

Abstract

The switch has a fixed contact (4) with smaller dimension and electrically connected to a movable contact that has curved arms (2, 3) forming a branch. The contact (4) is engaged between a pair of fingers (21, 31), in closing position of the switch. A clevis and a spacer are connected to ends of the arms to permit lever effect that amplifies electro-dynamic pinch-off exerted on the contact (4) by the fingers.

Description

DIRECT-INSERT, SWIVEL-BASED GROUND DISCONNECT WITH SINGLE MOVEMENT

  An earthing switch comprising a movable contact assembly pivotable about an axis of rotation and a stationary contact arranged to be electrically connected to an end of said movable contact assembly when said assembly is brought into the closed position. of the disconnector.

  The invention relates more particularly to an earthing switch intended to be used in transmission and distribution installations of high-voltage electrical energy in the open air and even more particularly to a so-called direct-insertion and single-movement earthing switch. wherein the movement necessary to connect the movable contact assembly with the fixed contact is made by a simple rotation of the movable assembly. The mobile contact assembly is generally called mobile contact, and for the sake of simplicity we will use this name in the following description.

  The short-circuit current value that an earthing switch is able to tolerate depends directly on the overheating (the increase of its temperature with respect to the ambient temperature) under short-circuit conditions and, in particular, overheating of the contact area between the fixed contact and the moving contact. For example, it may be specified for an earthing switch to be able to withstand a short circuit current of the order of 50 kA for one second. The behavior of the earthing switch is all the better as the contact pressure between the fixed and moving contacts is high.

  Another characteristic of this type of disconnector is their behavior with respect to the electromagnetic solicitations which tend to open the electrical circuit of which the earthing switch is one of the components. If this happens, the earthing switch contacts tend to melt.

  In general, the best pre-existing solutions for the arrangement of an earthing switch use high contact pressures in the case of single-ground earthing switches, or a mechanical separation between the disconnector rotation mechanism and the contact system. in the case of so-called dual-action earthing switches. These two solutions are not really satisfactory because of their mechanical complexity and consequently their high cost.

  Until now, a good electrical contact between the contacts of a single-acting earthing switch is obtained by using very rigid elastic components, for example springs, which realize a high contact pressure but which induce pairs of even when the disconnector is not energized (these torques increase proportionally to the rated voltage of the disconnector). Good electrical contact between the contacts of a double-acting earthing switch is achieved by using complex mechanisms of articulation of the moving contact.

  Document US Pat. No. 4,490,595 describes a direct-insertion, single-motion earthing switch in which it has been sought to minimize the impact of the electromagnetic forces acting on the fixed and movable contacts, in particular during the passage of a current of short circuit. -circuit in contacts. An insulating stop blocks the rotation of the pivoting knife acting as a moving contact, and prevents the knife from being able to exit in the direction beyond the slot formed between two parallel flexible arms ensuring the role of fixed contact. This fixed contact is electrically connected to a metal casing at the potential of the earth.

  This configuration implies that the movable contact is electrically connected to a phase of the line, which has drawbacks in particular to ensure the control of the pivoting knife and to ensure the arrangement of the knife in the open position without posing problems of dielectric strength. On the other hand, the two flexible arms of the fixed contact must be sufficiently long and positioned so as to create when the disconnector is closed a loop current that allows to exert on the knife a force that holds it in abutment against the insulating stop . Such dimensioning of the fixed contact requires a large dielectric isolation distance in the space between the pivot of the knife and the fixed contact.

  Moreover, an electrodynamic pinch of the knife is created by the parallel currents flowing in the two flexible arms of the fixed contact and which generate a force of mutual attraction between these two arms. It should be noted that with such a configuration, the electrodynamic clamping force of the knife remains lower than the mutual attraction force which tends to bring the two flexible arms closer together.

  A first object of the present invention is to provide a direct-insertion and single-movement earthing switch in which the mobile part can be electrically connected to the earth, and in which the fixed part is of relatively small dimensions compared to the part movable to ensure a relatively low dielectric isolation distance between the fixed and movable parts in the open position of the disconnector.

  A second object of the present invention is to exploit the electromagnetic forces that are exerted in a direct insertion and simple-ground earthing switch when a short-circuit current passes through the contacts, to reinforce the maintenance of the disconnector in its fully closed position, and to enhance the mutual contact pressure between the fixed and movable contacts by virtue of an electrodynamic pinch effect provided by leverage amplification of the mutual attraction force which tends to bring together two parallel arms of the movable contact.

  Another object of the present invention is to provide a direct-insertion, single-movement earthing switch which can be set in motion by means of a low-torque control, and which makes it possible to dispense with springs to ensure the desired contact pressure between the fixed and movable contact elements.

  For this purpose, the subject of the invention is an earthing switch as defined in the preamble, characterized in that said movable contact assembly comprises two substantially parallel electrically conducting arms which are bent to each form at least approximately one L, each arm elbow comprising at least one flexible finger which extends at least on the shortest leg of the L, the fixed contact being arranged to be engaged between at least one pair of flexible fingers in the closed position of the disconnector, and that joining means are mechanically connected to the two respective ends of the two arms bent on the shorter branches of the L to allow a leverage effect that amplifies the electrodynamic pinch exerted on the fixed contact by the flexible fingers when a current of short circuit or fault current runs through the crank arms.

  The construction of an earthing switch according to the invention exploits the well-known electrotechnical principle of the elementary force which is exerted on a conductor when it is traversed by a current and when it is subjected to an induction field. On the basis of this principle, referring to FIG. 1, it is known that two parallel conductive elements d1 traversed in the same direction by a current I undergo a pulling force df which tends to bring them closer to one another. other, and that is proportional to the square of the current. Considering an electrical circuit consisting of two identical non-linear conductors arranged substantially parallel to each other and traversed by the same current I, these two conductors attract each other with a force FF which verifies the following relation: ## EQU1 ## (1) C 7_0 where 1, is the total circuit length of a conductor, li is the length of a straight elementary section of a driver circuit, and fi is the mutual attraction force of two segments parallel elements (1i and fi correspond to dl and df respectively for an elementary section).

  It is also known, with reference to FIG. 2, that each element of a loop circuit (like a coil) traversed by a current I undergoes a force df tending to move the loop away from the electric circuit.

  When the earthing switch is closed and a short-circuit current passes through the fixed contact and the parallel arms L of the moving contact, electromagnetic forces are created which tend to bring the two arm parts closer to one another. in L between which is disposed the fixed contact, which is used to obtain a clamping effect of the fixed contact between the ends of the two arms of the movable contact. At each L-arm of the moving contact, electromagnetic forces are also created which tend to move the partial circuit loop formed by this arm. Because the two L-shaped arms forming the moving contact are mounted to pivot integrally about the axis of rotation of this contact, the resultant of these electromagnetic forces tends to rotate the movable contact towards the side of the L which is opposite to the shorter branches. This effect is used to maintain the fixed contact bearing in the bottom of the slot formed by the spacer and the second parts of the arms of the movable contact so that the earthing switch remains locked in its closed position.

  The pinching and locking forces of the fixed contact in the slot of the moving contact, which are dynamic forces in that they occur only in the presence of a short circuit, are all the more important as the current short circuit circulating in the contacts is high. It is therefore understood that after closure of the disconnector according to the invention, the maximum contact force between the fixed contact and the movable contact is provided only during a short circuit. This makes it possible to use, for the current opening and closing operations of the disconnector, a low torque drive mechanism for driving the mobile contact in rotation.

  In an advantageous embodiment, a disconnector according to the invention has the following particulars: each L-shaped bent arm is slotted longitudinally on the two branches of the L to form the flexible fingers over the major part of an arm, so as to to obtain even more flexibility in the spacing of the ends of the fingers and to ensure optimum electrical contact between the fixed contact and the movable contact of the disconnector; - The joining means mechanically connected to the two respective ends of the two bent arms comprise a rigid yoke providing the function of a hinge node for an electrodynamic clamp whose levers are constituted by the flexible fingers of the two arms, this yoke comprising a rectangular plate, one face has two parallel shoulders on two opposite edges, each shoulder comprising at least two holes each penetrated by a rod adapted to provide a mechanical connection between the yoke and a flexible finger; - An electrically insulating abutment member carried by the movable contact is constituted by a bar of insulating material which is fixed in the middle of the yoke plate parallel to the two shoulders, this bar being gripped by the flexible fingers of the two parallel arms in the open position of the disconnector; metal plates are fixed to the flexible fingers of the two parallel arms, each metal plate having a beveled or rounded end on the side through which the stationary contact is able to be engaged in the moving contact, and the spacing between two metal screws in the open position of the disconnector is less than the width of the fixed contact; the two parallel arms are extended axially on their longest branches by a conductive rod rotatably mounted about the axis of rotation of the movable movable contact assembly.

  Other types or embodiments of an earthing switch according to the invention are described in more detail in the description which follows. A first embodiment is described in more detail and is illustrated by the drawings of Figures 3 to 5. A second embodiment including the previously summarized advantageous embodiment is also described in more detail and is illustrated by the drawings of Figs. to 10.

  Figures 1 and 2 illustrate the electrotechnical principle of the elemental force used by the invention.

  - Figure 3 shows a partial perspective view of an earthing switch according to the invention in a first type of embodiment.

  - Figure 4 shows a longitudinal sectional view of the earthing switch of Figure 3, in a plane parallel to an L-arm of the disconnector.

  - Figure 5 shows a partial view from above of the earthing switch of Figure 3.

  - Figure 6 schematically shows a partial top view of an earthing switch according to the invention in a second embodiment, and illustrates the principle of electrodynamic clamping amplified by a lever effect.

  FIG. 7 schematically represents a side view of the earthing switch of FIG. 6.

  - Figure 7a shows very schematically a top view of a visible element laterally in Figure 7.

  - Figure 8 shows a partial perspective view of an earthing switch according to the invention 35 in an advantageous embodiment of the second type.

  FIG. 9 shows a partial view from above of the earthing switch of FIG. 8.

  FIG. 10 schematically represents a detail of an alternative to the earthing switch of FIG. 9.

  An earthing switch according to the invention, for high voltage applications, is a so-called direct insertion and simple movement disconnector. It is formed by a first part movable in rotation and by a second fixed part.

  More particularly, as shown in Figures 3 to 5, the movable portion of the earthing switch is a contact 1 mounted on a conductive rod pivoting about an axis of rotation (not shown) and connected to the potential of the earth. This movable contact 1 comprises two parallel metal arms 2,3 bent to each form an L, and is able to rotate about 90 around the axis of rotation which is located in the axial extension of the longest branch of the arms in L. The movable contact 1 is electrically connected to the ground potential in its lower section and more precisely near the area of the axis of rotation, while the upper section of the movable contact (the shortest branch of the arms in L) makes electrical contact with the fixed part of the disconnector. This fixed part of the disconnector here is a cylindrical copper contact 4 which is inserted between the two shorter branches of the L-arms of the movable contact 1 when the disconnector is moved from its open position to its closed position. In FIGS. 3 to 5, the disconnector is shown in a complete closed position where the movable contact 1 is in electrical contact with the fixed contact 4.

  As seen in FIGS. 3 and 4, each L-shaped arm 2,3 comprises a first arm portion indicated by the references 2A, 3A which is formed by the longest leg of the L and extends from the axis of rotation to a second arm portion 2B, 3B forming the shorter branch of L. The second arm portion indicated by 2B, 3B extends substantially transversely (perpendicularly) to the first arm portion 2A, 3A .

  In an earthing switch according to the invention, it is not essential that the two branches of an L is strictly rectilinear. In particular, it is conceivable to give the longest leg a slightly convex shape to accentuate the curvature provided by the elbow of the L and possibly to reinforce the electromagnetic spacing forces of the circuit, that is to say the forces which exert in the direction of the arrow F2 in FIG.

  A hinge spacer E connects the free ends of the second arm portions 2B, 3B which are flexibly mounted in the sense that they can move independently.

  The spacer E defines with the second arm portions 2B, 3B an open U-shaped slot indicated by 5 and more visible in FIG. 5. This U-shaped open slot 5 constitutes the upper part of the movable contact 1.

  In the example of Figures 3 to 5, the second arm portions 2B, 3B are slit longitudinally to define flexible contact fingers providing even more flexibility in the elastic spacing. In particular, each second arm portion is split to define two superimposed flexible fingers 2B1,2B2; 3E1,3E2 and the spacer E here comprises two bolts 6 passing through each of the two juxtaposed fingers, for example 2B1,3B1 or 2B2,3B2 and each is locked by a nut 7. There is a small clearance between each nut 7 and a flexible finger of a portion 3B to allow a slight separation of the fingers of the parts 2B and 3B when the fixed contact 4 is engaged between these fingers, so to provide some initial contact pressure at zero or low current. Once the fixed contact has come into abutment in the bottom of the slot 5, the spacer E provides a hinge function with respect to the ends of the flexible fingers and allows the amplified electrodynamic clamping effect, when the second arm portions 2B , 3B tend to get closer as explained later in this.

  A cylindrical sleeve 8 of electrically insulating material surrounds the rod of each bolt 6 which ensures the independence of the structure of the bolt relative to a resistance to the short-circuit current.

  In general, the minimum spacing allowed between the two arms 2,3 is regulated by a shim 9 disposed between the two arms 2,3 of the movable contact 1 in the vicinity of the bend. This wedge prevents the two arms from coming too close when the moving contact is traversed by a short-circuit current.

  The second arm portions (the flexible fingers 2B1,2B2,3B1,3B2) are provided with copper plates such as to promote good electrical contact with the fixed contact 4, and are also provided with skis made of insulating material such as 11 ( more visible in Figures 4 and 5) extending longitudinally on the second arm portions and conferring a flared shape at the entrance of the slot 5 to facilitate the insertion of the fixed contact 4 in the slot 5 when closing of the earthing switch. As shown in FIGS. 4 and 5, each ski 11 extends in the extension of a copper plate 10 towards the rear of the elbow of each L-shaped arm. The free spacing between two opposite plates 10 is slightly smaller than the diameter of the cylindrical contact 4, so as to create the initial contact pressure mentioned above because of a slight elastic separation of the second arm parts when the contact 4 is engaged between the plates 10.

  Alternatively, the plates 10 may have a slightly greater thickness on the side of the spacer than on the side of the skis 11, so as to increase said elastic spacing and thus also the contact pressure force abutment and zero current. It is also conceivable to dispense with the insulating sleeve 8 provided that the plates 10 themselves comprise on the spacer side stop elements, for example constituted on at least two plates facing each other by two trapezoidal shoulders of each plate. to stop the relative displacement of the fixed contact 4 with respect to the slot 5. In this example, the two screw plates would form substantially a U-shaped slot, and the stop function for the fixed contact would be provided by these plates.

  The air gap between the plates and the bolts of the spacer would allow the independence of the spacer structure with respect to resistance to fault currents. It is to be understood from this example that a stop element for the fixed contact is not necessarily electrically insulating in an earthing switch according to the invention.

  It is not a priori indispensable, in an earthing switch according to the invention, that the shorter branches of the bent arms are split longitudinally. For example, to increase the elasticity of these branches, it may be envisaged to locally reduce the thickness and / or the height of the metal plate of the arms to have only one finger or flexible part per arm.

  The arm portions 2A, 3A of the movable contact are extended axially by a conductive rod 12 which is rotatably mounted at its free end about the axis of rotation of the movable contact 1. In the open position of the disconnector, the rod 12 is normally substantially horizontal. This rod is electrically connected to the ground by means of sliding contacts arranged at the axis of rotation of the movable contact, or by flexible metal cables. The fixed contact 4, meanwhile, is fixed to the live bar which corresponds to the phase that can be grounded by the disconnector.

  When closing the disconnector, the rod 12 with the L-shaped arms 2,3 is rotated at an angle of about 90 to a substantially vertical position. During the displacement of the movable contact 1 during the closing of the disconnector, the fixed contact 4 fits into the slot 5 by first passing at the elbows of the arms 2,3 between the skis 11 and finally abuts against the spacer E formed. The cylindrical fixed contact 4 which extends axially towards the axis of rotation is then moderately clamped between the copper plates 10 which are fixed to the flexible fingers 2B1, 3B1 and 2B2, 3B2.

  In the fully closed position of the disconnector, the conductive rod 12 with the first arm portions 2A, 3A is inclined with respect to a non-equilibrium vertical position while the cylindrical fixed contact is disposed in the bottom of the open-shaped slot. U, resting against the spacer; thus, even when no short-circuit current flows through it, the earthing switch is held in its closed position without it being necessary for the disconnector control mechanism to exert a torque in the opposite direction. closing on the mobile contact 1 pivoting.

  In the foregoing, electromagnetic forces have been ignored to consider only a static mechanical pinch of the fixed contact under the effect of the elastic forces which tend to bring the second arm parts closer together because of their flexibility. But if we consider a closed state of the disconnector with passage of a short circuit current or fault current, we must take into account the electrodynamic pinch effect provided by the electromagnetic forces. The pinching of the fixed contact by the flexible fingers then becomes much more important. By fault current is meant a current greater than the nominal current that may pass through the line conductor that supports the fixed contact 4. The spacer E, and in particular the bolts 6 associated with the nut 7, prevents any further separation of the ends of the flexible fingers once the fixed contact 4 positioned in abutment, and has a hinge role for an electrodynamic clamp whose two opposite levers are formed by the second arm portions 2B, 3B. This makes it possible to amplify at the fixed contact the force of mutual attraction as defined by the preceding relation (1) and which tends to bring the opposite levers of the clamp, in particular at the level of the flexible fingers. It is recalled that the mutual attraction force FF is proportional to the square of the current flowing through the electrical circuit of the earthing switch.

  This results in a pressure force of the flexible fingers against the fixed contact which is much greater than the force FF due to the electrodynamic effect exerted on the second arm portions 2B, 3B. The fixed contact 4 being in abutment against the spacer, the pressure zones of the plates 10 against this contact are indeed closer to the axis of the spacer, that is to say the hinge of the clamp. This nip amplification effect is particularly advantageous compared to a conventional device as shown in US-4490595, in which the parallel flexible arms do not act as levers of a nut cracker because of the absence of hinge element at the end of the arms.

  The line of axial alignment of the cylindrical fixed contact 4 with the axis of rotation of the moving contact is represented by the substantially vertical line 1v in FIG. 3, and it can be seen in this figure that the rod 12 with the arm portions 2A , 3A extend in a longitudinal direction which is inclined relative to the line lv of a non-zero angle of a few degrees. The fixed contact is then in abutment against the spacer E of the movable contact 1, ensuring the latter a stable closed position. When a fault current flows through the arms 2,3, while the disconnector is in its closed position, electromagnetic attraction forces tend to bring together the second arm portions 2B, 3B which bear the opposite flexible fingers 2E1. , 3E1,2E2,3E2, with the effect of an electrodynamic pinch of the fixed contact 4 between the two arms of the upper part of the movable contact. In this way, an optimum electrical contact is ensured between the fixed and movable contacts 1, 4 since the clamping force exerted is amplified relative to the resulting electromagnetic attraction force Fa on the two arms. The electrodynamic pinch effect is illustrated later in FIG. 6 in connection with another embodiment of an earthing switch according to the invention.

  Since the spacer is electrically insulated from the fixed contact 4 by the sleeve 8, it does not have to be thermally sized to withstand the short-circuit currents, which makes it independent of the amplitude of the short circuit current from a structural and thermal point of view. In addition, electromagnetic forces are exerted in the direction of the arrow F2 on the arms 2, 3 bent, which tend to bring the fixed contact 4 of the spacer E with the effect of blocking the fixed contact 4 in the bottom of the slot 5 and therefore an emphasis on maintaining the disconnector in its closed position. It should be noted that this is possible because in the closed position of the disconnector, the state of the rod carrying the movable contact is inclined with respect to the position of the line IV, and the electrodynamic effect which tends to open the circuit in L allows to further push the rod 12 with the arms bent in the direction of closing the disconnector. As indicated above, these electromagnetic forces are dynamic and even stronger than the short-circuit current is high.

  In FIG. 6, the principle of leveraged electrodynamic clamping is illustrated for a second type of embodiment of an earthing switch according to the invention. The disconnector is shown schematically in partial view from above. The conductive rod in the extension of the two parallel arms 2,3 and the wedge between the arms in the vicinity of the elbow are not shown. The difference with the first type of embodiment in relation to FIGS. 3 to 5 relates mainly to the joining means which are mechanically connected to the two respective ends of the two bent arms on the shorter branches of L. These joining means do not include not in this case a spacer itself, in the sense that the rigid part 13 is not interposed between the flexible fingers of the two parallel arms. But this piece 13 forms a kind of stirrup which has a section substantially in C and which limits the spacing of flexible fingers. This piece thus performs the same function as the spacer E in the first type of embodiment. In general, the joining means of these two embodiments provide the function of a hinge node for an electrodynamic clamp whose levers are constituted by the flexible fingers of the two parallel arms. In what follows, the piece 13 is called a screed.

  In the closed position of the disconnector shown in FIG. 6, the fixed cylindrical contact 4 is engaged in abutment in the bottom of the U-shaped slot 5 which is defined by the yoke 13 and by the shorter branches of the two parallel bent arms. . For the sake of simplicity of the commentary of FIG. 6, only the parallel flexible fingers 21 and 31 will be considered for the explanation of the electrodynamic pinch, but the same explanation is valid for the other pairs of flexible fingers facing each other. When a current of short-circuit or fault current traverses the parallel flexible fingers 21 and 31, it results on the two fingers an electromagnetic attraction force F1 can be determined in the same way as the force FF in the relation (1) . This force of attraction F1 resulting from the summation of the elementary forces along the length of the flexible fingers returns to a unique force of attraction whose point of application on each finger is approximately half of the length of the finger. Thus, given the relatively long length of the flexible fingers in this second embodiment, the distance L1 between the point of application of F1 and the hinge node provided by the joining means is approximately equal to the length of the branch. shorter bent arms. This distance L1 is in any case much greater than the distance L2 between one or the other of the two points of application of the clamping force F3 of the fingers 21 and 31 on the fixed contact 4 and the hinge node.

  As with any nut-type mechanical clamp, we have here the relation F1 Li = F3 L2, ie F3 = F1 L1 / L2, which implies that a lever effect amplifies with a coefficient equal to L1 / L2 the force of electromagnetic attraction F1 exerted on the levers which are constituted by the parallel flexible fingers 21 and 31, to obtain the pinching force F3 exerted on the fixed contact 4.

  The distance L2 can be modified to a certain extent by modifying the height of the insulating bar 19 which serves as a stop means for the fixed contact 4 and which is fixed inside the yoke 13 by a bolt associated with a nut 15 On the other hand, as explained further in the commentary of Figure 9, it should be understood that this bar 19 also serves as a stop means for limiting the approach of the flexible fingers facing in the open position of the disconnector. More specifically, in this open position, there is provided a prestressing force which tends to bring together the two parallel arms 2 and 3, and the bar 19 is clamped by the metal plates of each pair of flexible fingers screw to screw. This allows an increase in the static nip exerted on the fixed contact 4 in the absence of fault current in the disconnector. The width 12 of the fixed contact, in this case the diameter of the cylinder forming this contact, is therefore necessarily greater than the width of the bar 19.

  In Figure 7, the earthing switch of Figure 6 is shown schematically by a side view perpendicular to the plane formed by the bent arm 3 of the disconnector. A further difference can be seen with the first type of embodiment in connection with FIGS. 3 to 5: the shorter branches of each bent arm 2 or 3 are split longitudinally along their length to form flexible fingers, and the slots extend beyond the elbow over a large part of the longest branch of each arm. The flexible fingers obtained are thus bent with the same L-shape as the arms, which increases the elasticity of each finger and increases the effective lever length for the amplification of the electrodynamic pinch by an effect of leverage. This makes it possible to obtain an electrodynamic clamp producing a contact pressure on the fixed contact 4 which is greater than that obtained in the first embodiment.

  The choice of one-piece type joining means such as the yoke 13 makes it possible to produce a heavier hinge node and a lower manufacturing cost than the production of a spacer E with bolts. In addition, it is advantageous in this particular embodiment to have three flexible fingers such as 31, 32 and 33 on each bent arm, in order to further increase the elasticity of each finger, and to have a finger length. which increases as it gets closer to the inside of the elbow.

  The wedge 9, located behind the bent arm 3 in this side view, is traversed by two bolts 16 and is free to slide between the two parallel bent arms with a small game along the rods of the bolts. In Figure 7a, we can see that this small game is twice the spacing j. The function of this shim 9 has been explained previously for the first type of embodiment.

  In Figure 8, a ground switch of the second type according to the invention is shown in a partial perspective view. This advantageous embodiment is almost identical to that in relation to FIGS. 6 and 7, and corresponds exactly to one or the other of the embodiments shown respectively in FIGS. 9 and 10. single-phase line conductor which supports the fixed contact 4. The earthing switch is in an intermediate open position, and the movable contact assembly 1 is pivoting to operate for example closing the disconnector.

  A partial view from above of the earthing switch of FIG. 8 is shown in FIG. 9, in a position where the mobile contact assembly is about to come to connect with the fixed contact 4. Wedge 9 is not shown in this view. Unlike the embodiment in connection with Figures 6 and 7, the holes 18 of the shoulders of the yoke 13 do not have threading and are not intended for tightening a bolt. The yoke 13 comprises a rectangular plate 13C whose inner face to the yoke has two shoulders 13A and 13B parallel to the two opposite edges which are intended to provide a mechanical connection with the flexible fingers and their metal plates 10 '. Each shoulder 13A or 13B comprises three holes 18 each penetrated by a rod 14 adapted to provide this mechanical connection between the yoke and a finger such as 21 or 31.

  A sleeve of insulating material 24 is interposed between the wall of a hole 18 and the rod 14 which enters this hole. The portion of the rod that enters the hole 18 is not threaded and is constituted by the end of a bolt that allows the clamping of a plate 10 'against a finger such as 21 or 31 in combination with means The open U-shaped slot has a flared inlet which is formed by the metal plates 10 ', each plate having a tapered end at the entrance to the slot. Each plate has near its beveled end a threaded hole for fixing the plate on an arm 2 or 3 by means of a bolt 17. It is visible that the spacing 11 between two plates 10 'opposite, in the position open of the disconnector, is less than the width of the fixed contact 4.

  The clamping means 25 have an abutment member arranged to limit to a predetermined distance d the sliding of the rod 14 in said insulating sleeve 24 when closing the disconnector in the presence of a strong current. This predetermined distance is close to the amplitude e of separation of a flexible finger defined as half of the difference between the spacing 11 and the width 12 of the fixed contact 4. It is indeed the following relation: e = 0 , 5 (11 - 12).

  The width of the bar 19 determines the spacing 11 between two plates 10 'facing. The bar 19 is preferably made of the same electrically insulating material, and here has portions which have a substantially rectangular cross-section so as to constitute an abutment element 8 'for the fixed contact 4. However, an insulating bar with only section U is possible, provided to provide another insulating material in the inner space of the bar to cover the head of the bolt 15 and provide the stop function. The electrical insulation properties of the bar 19 and its stop element 8 'make it possible on the one hand to isolate, with respect to the joining means, each end of an arm 2 or 3, and on the other hand to isolate between them the two respective ends of the arms 2 and 3.

  In FIG. 10, each rod 14 has a first threaded portion 14A which cooperates with the clamping means 25 to contribute to the fixing of a metal plate 10 'to a flexible finger, and a second non-threaded portion 14B able to slide in the insulating sleeve 24. The mounting of the yoke 13 is facilitated in this embodiment, because the rod 14 can be introduced by the right of the sleeve 24 in the figure, unlike the embodiment of Figure 9. As for the previous embodiment , the stop member 26 of the clamping means 25 is arranged to limit at a predetermined distance d the sliding of the second portion 14B of the rod in the sleeve 24. Compared with the embodiment in connection with FIGS. 7, it may be noted that each rod 14 alone provides both the mechanical connection function between the yoke 13 and a flexible finger and the function of fixing a metal plate 10 'on a d oigt, while these two functions are exerted by two separate bolts in the device of Figure 6. This construction also reduces the height of the bar 19 in the plane of the figure, thereby reducing the distance L2 shown in Figure 6 while ensuring that the contact area between the fixed contact 4 and the plates 10 'does not have a bolt hole. The leverage amplification of the electrodynamic pinch of the fixed contact is thus increased with respect to the device of FIG. 6.

  Alternatively, the yoke 13 could be replaced by a metal frame of rectangular shape whose uprights perpendicular to the fingers 21 and 31 are pierced with holes having the function of the holes 18 of the shoulders 13A and 13B. An insulating material covering the upper and lower amounts of the frame could be sufficient to provide the function of insulating abutment member for the fixed contact.

  The construction of an earthing switch according to the invention allows the entire locking system in the closed position is provided by the movable contact. In addition, in the open position of the disconnector, it is possible to easily maintain the desired dielectric distance in the gap between the fixed contact and the movable contact since the fixed contact may be small. In other words, the axis of rotation of the movable contact can be arranged at a distance relatively close to the bar which supports the fixed contact. In this way, it is possible to ensure with a small footprint the resistance to high voltages in an opening configuration of the earthing switch.

Claims (18)

  1 / Earthing switch comprising a movable contact assembly (1) pivotable about an axis of rotation and a fixed contact (4) arranged to be electrically connected to an end of said movable contact assembly (1) when said assembly is brought in the closed position of the disconnector, characterized in that said movable contact assembly (1) comprises two substantially parallel electrically conductive arms (2, 3) which are bent each to form at least approximately one L, each bent arm (2, 3) comprising at least one flexible finger (2B1, 2B2, 3E1, 3B2; 21, 23, 31, 33) which extends at least on the shorter branch of the L, said fixed contact (4) being arranged to be engaged between at least one pair of flexible fingers in the closed position of the disconnector, and in that jointing means (E, 13) are mechanically connected to the two respective ends of the two bent arms (2, 3) on the shortest branches s L to allow a leverage effect that amplifies the electrodynamic pinch exerted on the fixed contact (4) by said flexible fingers when a short-circuit current or fault current flows through said arms (2, 3).   2 / Earthing switch according to claim 1, wherein the fixed contact (4) and the movable contact assembly (1) are arranged relative to each other such that in the fully closed position of the disconnector, the fixed contact is in abutment against an electrically insulating abutment element (8, 8 ') carried by the movable contact assembly.   3 / Earthing switch according to one of claims 1 and 2, wherein the fixed contact (4) has the shape of a substantially cylindrical stud whose axis defines a line (lv) substantially vertical, and wherein said line extends axially towards the axis of rotation of the movable contact assembly (1).   4 / Earthing switch according to one of claims 1 to 3, wherein the shorter branches (2B, 3B) of each L-shaped bent arm (2, 3) are split longitudinally to form flexible fingers (2B1 , 2B2, 3B1, 3B2).   5 / Earthing switch according to claim 4, wherein the longer branches of each L-shaped bent arm (2, 3) are also slit longitudinally, so as to obtain flexible fingers (21, 23, 31, 33). ) bent in the shape of L. 6 / Earthing switch according to one of claims 1 to 4, wherein said joining means consist of a spacer (E) which comprises a sleeve (8) of electrically insulating material which surrounds a bolt (6) passing through two flexible fingers (2B1, 3B1, 2B2, 3B2) of the two parallel arms (2, 3).   7 / Earthing switch according to claim 5, wherein said jointing means comprise a rigid yoke (13) providing the function of a hinge node for an electrodynamic clamp whose levers are constituted by the flexible fingers of the two parallel arms (2, 3).   8 / Earthing switch according to claim 7, wherein said yoke (13) comprises a rectangular plate (13C), one side has two shoulders (13A, 13B) parallel on two opposite edges, each shoulder having at least two holes (18). ) each penetrated by a rod (14) adapted to provide a mechanical connection between said yoke and a flexible finger of a bent arm (2, 3).   9 / Earthing switch according to claim 8, wherein a sleeve of insulating material (24) is interposed between the wall of a hole (18) and the rod (14) which enters this hole.   10 / Earthing switch according to one of the preceding claims, wherein metal plates (10 ') are fixed to the flexible fingers of the two parallel arms (2, 3), each metal plate having a beveled end or rounded side by which the fixed contact is able to be engaged in the movable contact assembly, and in which the spacing (11) between two metal plates (10 ') facing the open position of the disconnector is less than the width (12 ) of the fixed contact (4).   11 / Earthing switch according to claim 10 taken in combination with claim 9, wherein said rod (14) has a first portion (14A) threaded which cooperates with clamping means (25) to contribute to the fixation of a metal plate (10 ') on a flexible finger (31) and a second unthreaded portion (14B) slidable in said insulating sleeve (24), and wherein said clamping means (25) has an abutment member (26); ) arranged to limit to a predetermined distance (d) the sliding of said second portion (14B) in said insulating sleeve (24) when closing the disconnector in the presence of a strong current.   12 / Earthing switch according to claim 11, wherein said predetermined distance (d) is close to the amplitude (e) of separation of a flexible finger (21, 31) defined as half of the difference between the spacing (11) between two metal plates (10 ') and the width (12) of the fixed contact (4).   13 / Earthing switch according to one of claims 10 to 12 taken in combination with claim 8, wherein the electrically insulating abutment element (8 ') which is carried by the movable contact assembly is integral with a electrically insulating bar (19) having U-section portions and being fixed in the middle of the plate (13C) of said yoke (13) parallel to the two shoulders (13A, 13B), and wherein said insulating bar is taken in vice by the flexible fingers of the two parallel arms (2, 3) in the open position of the disconnector.   14 / Earthing switch according to claim 13, wherein said stop element (8 ') is constituted by portions of said insulating bar (19) which have a substantially rectangular section.   15 / Earthing switch according to one of the preceding claims, wherein a shim (9) is disposed between the two parallel arms (2, 3) in the vicinity of their elbows and defines a minimum allowed spacing between the two arms when said 30 movable contact assembly (1) is traversed by a short-circuit current.   16 / Earthing switch according to one of the preceding claims, wherein the two parallel arms (2,3) are axially extended on their longest branches by a conductive rod (12) rotatably mounted about the axis of rotation of the pivoting contact assembly (1).   17 / Earthing disconnector according to claim 16, wherein in the closed position of the disconnector, said conductive rod (12) is inclined relative to a vertical position of non-equilibrium.   18 / Earthing switch according to claim 5, wherein each L-shaped bent arm comprises three flexible fingers (31, 32, 33).