NO964375L - Disconnector, especially medium voltage disconnect switch - Google Patents

Abstract

The disconnecting or insulating switch has support insulators (4). An insulating contact is arranged at each terminal of the insulator (4). The switch has a movable contact blade, a lag contact and a closed explosion chamber (10) with a movable switch pin. The chamber (10) is preferably filled with SF6 gas. The switch has a support insulator (4) with an integral explosion chamber (10) per terminal. The explosion chambers (10) are preferably disposed between the support insulators (3,4) of a terminal. The chamber (10) may be integrated in the support insulator at which the pivot point of the contact blade is disposed.

Description

CIRCUIT BREAKER, IN PARTICULAR MEDIUM VOLTAGE LOAD CIRCUIT BREAKER

The invention relates to a disconnector, in particular a medium-voltage load disconnector with supporting insulators, where for each pole there is a disconnector contact with a movable disconnector knife, a lagging contact and a closed extinguishing chamber which is equipped with a movable contact pin, and which is particularly filled with SFs gas.

From the German patent document 1 154 170 such a switch-disconnector is known, where the extinguishing chamber is located in a secondary current path which immediately after opening the main contact only briefly conducts current through the extinguishing chamber via the lagging contact which only temporarily remains in the switched-on position, until the current circuit is broken through the movable contact pin of the extinguishing chamber which separates from the counter contact, and the resulting arc in the extinguishing chamber is extinguished.

The advantages of arranging the extinguishing chamber in a bi-current path are particularly to be found in that the extinguishing chamber is not constantly current-carrying, and due to the short-term current flow can be constructed relatively small with a relatively low weight as a result, which in turn leads to a good switching speed of due to the low weight.

Nevertheless, there are significant disadvantages to the known load disconnect switch. thus, this known extinguishing chamber arrangement entails a relatively large space requirement, and also requires, in order to achieve the connection sequences in connection with the breaking of the main and secondary flow path, a considerable structural and thus disturbance-tolerant structure.

The invention has the task of simplifying the switch structure for the switch mentioned at the outset while maintaining the basic advantages of the arrangement of an extinguishing chamber in the by-current path, in particular to reduce the space requirement and improve the switching effect of the switch.

According to the invention, this task is solved through a support insulator with an integrated extinguishing chamber for each pole, whereby the extinguishing chamber in the preferred embodiment is in each case located between the support insulators of a pole. While the extinguishing chambers in this type of switch have until now formed separate construction units, which could often only be assembled at great cost, and the dimensions of the switches, due to the cumbersome structure, also determined the dimensions of the switch cell into which they were to be built, the invention results in an extremely compact and space-saving construction paired with a very high connection reliability and connection speed.

A particularly favorable construction, not only in the sense of small space requirements, but also with a view to optimal routing of the auxiliary current path, then appears when the extinguishing chamber is integrated into the relevant support insulator which carries the main contact with the knife pivot point. In a way that will be described in more detail below, the secondary current path can thereby be created in a simple way through a comparatively short cable connection between the lagging contact and the extinguishing chamber.

As already mentioned, the lagging contact ensures that the current briefly and temporarily flows in a secondary path, as soon as the knife breaks the main current path through the opening of the assigned separating contact, until the movable contact pin inside the extinguishing chamber then detaches from the fixed contact, and the disconnection process is thus completed.

In order to ensure this transient by-flow path in a particularly simple way, and to be able to match the lagging contact to the movement of the separating knife as favorably as possible in order to achieve an optimal coupling sequence, it has been shown to be correct that the separating knife carries an oppositely insulated and pivotable lagging pin.

It contributes to a further reduction of the structural size when the separating knife is split lengthwise, and between the two separating knife halves a coupling kinematics is provided for the extinguishing chamber which ensures a particularly reliable and high coupling speed. This coupling kinematics preferably cooperates with the extinguishing chamber's contact pin and the separating knife, that is to say that depending on the position of the contact knife at any time, the coupling kinematics ensures the right time when the contact in the extinguishing chamber is to be broken and the spark is extinguished.

Under the conditions present here, a kinematics seems particularly reliable consisting of an arm mechanism, where an angle arm has proven correct, which angle arm with its one end is linked to the extinguishing chamber contact pin, while its other end is stored in a joint location that forms a joint connection between the free end of a to a fixed point joint-connected link arm and the free end of a release rod operated by the separating knife. Such kinematics stored between the separating knife halves not only ensures a precisely coordinated separation sequence as far as the individual movement drains are concerned, but also ensures a compact, space-saving structure and, due to the low weight, leads to fast coupling sequences.

As already mentioned, the kinematics ensures that the extinguishing chamber's movable contact pin detaches from its fixed counter contact exactly at the desired time, until which the contact pin is held through the kinematics against the prevailing overpressure in the extinguishing chamber of approx. bar.

In order to fulfill this function, two versions of the kinematics are preferably calculated, and the kinematics can namely, for one, be provided with a pawl which is stored to the angle arm connected to the extinguishing chamber contact pin, and which cooperates with a fixed stop pin, and in whose pivot point a torsion spring that exerts engagement forces on the rivet, whereby there is a stop pin for the free rivet end at the separating knife, while in the other version a pressure spring is arranged on the angle arm which is connected to the extinguishing chamber contact pin, which rests on the separating knife. The operation of these two editions is described in even more detail in the following description of the preferred design examples.

The secondary current path, which briefly takes over the current flow, is provided by the lagging contact being electrically connected to the fixed contact in the extinguishing chamber, preferably via a cable, while the movable extinguishing chamber contact is electrically connected to the separating knife pivot point through the kinematics.

Using the attached drawings where preferred embodiments of the invention are shown, these are explained in more detail below. The drawings show: Fig. 1, a side view of a switch-disconnector; Fig. 2, an elevation of the three-pole load disconnect switch according to fig. 1, front view; Fig. 3a, a preferred operating kinematics with compression spring in engaged state; Fig. 3b, the operating kinematics according to fig. 3a in an intermediate position where the separating knife has just disengaged from the separating contact, while the lagging contact pin and the extinguishing chamber contact pin are still in contact with their associated fixed contact, that is to say that the current now flows over the secondary current path; Fig. 3c, the kinematics according to fig. 3a and 3b in the disengaged state; Fig. 4a, a second version of the operating kinematics with a release pawl in the engaged state; Fig. 4b, the kinematics according to fig. 4a in the intermediate position according to fig. 3b; and Fig. 4c, the kinematics according to fig. 4a and 4b in the disengaged state.

In fig. 2 shows an embodiment of a switch unit as medium voltage load disconnect switch 1, where it can be seen that the switch unit's three poles A, B and C are attached to a common base frame 2. Taken together with fig. 1, where the switched-off state of the switch versus the switched-on state is depicted with a dash-dotted line, it becomes clear that each pole is attached with two insulators 3 and 4 to the base frame 2, whereby the upper support insulator 3 in the example of the embodiment produced is in each case the separating contact support, while that for the lower support insulator 4 is about the pivot contact support. Therefore, the upper support insulator 3 carries a connection-respectively separation contact 5, while a contact piece carried by the lower support insulator 4 is denoted by 6 and exhibits a pivot contact 7.

The connection between the contact pieces 5 and 6 is achieved through a separating knife 8 which is pivotable about the pivot point contact 7, and which, as can be seen from fig. 2, is divided in the longitudinal direction. On the outside, one of the two separating knife halves carries a lagging contact in the form of a lagging contact pin 9 which is insulated opposite the separating knife 8 and is pivotally mounted on it. The function of this lag pin is described in more detail below.

In order to extinguish the spark that occurs at the final breaking of the current circuit, quickly and without affecting the surroundings, each pole A, B and C is provided with an extinguishing chamber 10 which is integrated in the pivot contact insulator 4, and then so that it lies on the the separating contact insulator 3 on the opposite side of the pivot point contact insulator 4, whereby a particularly compact and space-saving device is achieved, as can also be seen from fig. 2, since each extinguishing chamber thus lies within the surface of the base frame 2 which is essentially defined by the spacing of the support insulators.

A movable contact pin 11 projects from the extinguishing chamber 10 on the side facing the separating knife 8 and cooperates with a fixed contact 1a in the extinguishing chamber 10 in a manner to be explained in connection with the explanation of an auxiliary current path 12. Opposite the atmosphere outside is the interior of the extinguishing chamber 10, which stands below an overpressure which in the specific example is approximately bar, sealed through a membrane 11b which, for the sake of overview, is only shown in fig.1, and which follows the contact pin 11's movements in the same way as a piston plate lic provided with bores which serve for the blowing of the spark gap at the separation of the contacts 11, lia.

Via each so-called operating isolator 13, each separating knife 8 or both of the knife halves belonging to each knife are operationally connected to a common drive shaft 14 for the three poles A, B and C in a manner that appears in fig. 1. As further appears from fig. 2, the operating insulators 13 lie flush between the separating knife halves 8.

The desired movement coordination between separating knife 8, lagging pin 9 and movable extinguishing chamber contact pin 11 is achieved through a coupling kinematics 15, which is explained with the help of fig. 3a to c and fig. 4a to c.

Fig. 3a to c show a first variant of a kinematic design, where the parts of the disconnect switch 1 which are not absolutely necessary for the explanation are omitted or simplified for the sake of overview. This kinematics 15 essentially consists of an angle arm 16 as a transfer arm, which with its one end 16a is articulated with the extinguishing chamber contact pin 11. Its other end is stored to a joint location 16b which forms a joint connection for the free end of a release rod 17, which becomes served by the separating knife 8, with the free end of an articulated arm 18 which is articulated with a fixed point 18a.

At the point of connection between the kinematics 15 and the separating knife 8, a freewheel is provided on the release rod 17 which controls the sequence of positions, i.e. the different movement sequences, which freewheel in the preferred embodiment consists of a slot 19, through which protrudes a stop pin 20 which is attached to the separating knife 8. In order to keep the extinguishing chamber 10's movable contact pin 11 against the excess pressure in the extinguishing chamber in the switch-on position until a time defined in more detail below, the angle arm 16 carries a compression spring 21, which on one side rests on the angle arm and on the other side on the separating knife 8. The way it works for this kinematics 15, the structure of which has been explained earlier, is as follows: Fig. 3a shows the kinematics 15 in normal, engaged state. If a disconnection is to take place, the separating knife 8 is first turned anti-clockwise to the one in fig. 3b produced intermediate position, where, as can be seen from fig. 3b, the lag pin 9 as well as the kinematics 15 remain in that of fig. 3a manufactured position. Thus, the main current path is broken through the pulling of the knife 8 from the separation contact 5, while the current now flows via the auxiliary current path 12, that is from the upper connection contact 5 via the lagging pin 9 and further via a cable 9a and an electrical connection between this and the extinguishing chamber 10 fixed contact 1a,

via the movable extinguishing chamber contact pin 11 and it

with the separating knife 8 electrically connected kinematics 15 to the pivot point contact 7 of the lower contact piece 6.

At this point, the compression spring 21 has already relaxed somewhat, but still acts so strongly on the movable contact pin 11 that it does not detach from the fixed contact 1a in the extinguishing chamber 10. Now the stop pin 20 in the slot 19 has reached the left limiting edge of the slot and further affects the release rod 17 for a rotation of the kinematics 15 also in the clockwise direction and rotates the angle arm 16 also in the clockwise direction. First by this further movement of the separating knife 8 and now also by the kinematics 15 in the clockwise direction, the pressure spring 21 relaxes so much that it is no longer able to withstand the overpressure prevailing in the extinguishing chamber 10, and the movable contact pin 11 therefore detaches from the fixed counter contact lia, and shortly before the lagging pin 9 is separated from the separating contact 5.

Through the contact-breaking movement of the movable contact pin 11, the associated piston plate lic is moved to the left, whereby the pressure in the left part of the inside of the extinguishing chamber 10 is increased, which, due to the bores located in the piston plate lic, leads to a gas flow that unfolds to quenching effects in the direction of the arc that occur when the contacts 11 and lia are separated and thereby interrupt the current flow.

Shortly after the separation of the contacts 11 and 11, the now de-energized lagging pin 9 is released from the connection contact 5 and brought to the one in fig. 3c produced parallel position with the separating knife 8. From fig. 3c also shows the relative position of the rod parts 16, 17 and 18 of the kinematics 15 in the disengaged state.

Fig. 4a to c show a preferred variant of the design of the kinematics 15, which differs from the kinematics whose construction was explained earlier in connection with fig. 3a to c, only with regard to the design that causes the counterforce against the internal pressure of the extinguishing chamber 10, namely this mechanism 15 has a latch 22 which is preferably rotatably stored in the elbow of the angle arm 16 and is held in the engaging position by a torsion spring 23, as in one side rests on the angle arm 16 and on the other side on the latch 22, in which engagement position the latch 22 with a hook-shaped end engages behind a fixed point (pin) 24 and thereby indirectly, namely via the angle arm 16, as a counter-pressure component compensates for the overpressure of the extinguishing chamber . The separating knife 8 carries a release stop 25 which, in the desired angular position of the separating knife, acts on the free end of the latch 22.

The movement sequence of the individual parts in question as well as the connection and disconnection order of the leading parts essentially correspond to those previously explained in connection with fig. 3a to c, so that in the following only the differences that appear through the "clamp version" during the disengagement process are explained.

Fig. 4a again shows the engagement position of the kinematics 15, while fig. 4b shows the separating knife 8, which has already been pulled from the contact 5, in the position rotated in the clockwise direction, at which time the impact pin 20 has the explained effect on the kinematics occurs. At this moment, the lagging pin 9 is again still in electrical connection with the contact 5, so that the current now flows along the previously explained secondary current path, until, by further turning the separating knife 8 in a clockwise direction at the contact of the stop pin 20 on the left edge of the slot 19, a movement of the kinematics 15 again in the clockwise direction, at which point finally a relative rotation - in the clockwise direction - of the latch 22 takes place via the trigger stop 25 which thereby disengages from the fixed point 24 and thus cancels the force acting against the internal pressure of the extinguishing chamber 10, so that its contact pin 11 can detach from the counter contact 11a, thereby breaking the flow of current. Shortly thereafter, the lagging pin 9 ends up in the parallel position to the separating knife 8, as shown in fig. 4c.

For both variants, the switch-on process can take place in a simple way by rotating the disconnecting blade 8 in a clockwise direction to its switch-on position at the disconnecting contact 5. With this turning movement, the disconnecting blade 8 also causes, through the previously explained mechanical connections in detail, the return of the other switch parts to their initial position (switched-on position ) according to fig. 1, 3a and 4a.

Claims (17)

1. Disconnector, in particular medium-voltage load disconnector with support insulators, where for each pole there is a disconnecting contact with a movable disconnecting blade, a lagging contact and a closed extinguishing chamber which is equipped with a movable contact pin, and which is in particular filled with SFg gas, characterized by a support insulator (4) with integrated extinguishing chamber (10) for each pole. 2. Disconnector according to claim 1, characterized in that the extinguishing chamber (10) is in each case located between a pole's support insulators (3, 4). 3. Disconnector according to claim 1 or 2, characterized in that the extinguishing chamber (10) is integrated into the support insulator (4) on which there is a disconnection knife pivot point (7). 4. Disconnect switch according to one or more of claims 1 to 3, characterized by a lagging contact pin (9) which is carried by the disconnect knife (8) and is insulated and rotatable in relation to it. 5. Disconnect switch according to one or more of claims 1 to 4, characterized by a longitudinally divided disconnecting knife (8) and a coupling kinematics (15) for the extinguishing chamber (10) arranged between the two separating knife halves. 6. Isolation switch according to one or more of claims 1 to 5, characterized in that the coupling kinematics (15) is in cooperative connection with the extinguishing chamber (10) contact pin (11) and the separation knife (8). 7. Disconnector according to claim 6, characterized in that the switching kinematics (15) consists of an arm mechanism. 8. Disconnector according to claim 7, characterized by an angle arm (16) which with its one end (16a) is articulated with the extinguishing chamber (10) contact pin (11), while its other end is stored to a joint location (16b) which forms a joint connection for the free end of an articulated arm (18) articulated to a fixed point (18a) and the free end of a release rod (17) which is operated by the separating knife (8). 9. Separating switch according to one or more of claims 6 to 8, characterized by a freewheel at the connection point between the kinematics (15) and the separating knife (8). 10. Disconnect switch according to claim 9, characterized in that the free run consists of a slot (19) in the free end of the release rod (17), through which slot (19) protrudes a pin (20) attached to the disconnect knife (8). 11. Isolation switch according to one or more of claims 1 to 10, characterized by a static force which counteracts the overpressure of the extinguishing chamber (10). 12. Isolation switch according to claim 11, characterized by a spring (21; 23) which acts on the angle arm (16) which is connected to the contact pin (11) of the extinguishing chamber (10). 1 3. Disconnect switch according to claim 11 or 12, characterized by a latch (22) which is stored to the angle arm (16) and cooperates with a fixed stop pin (24), and in whose pivot point is stored a torsion spring (23) which exerts engagement forces on the latch (22) . 14. Separating switch according to claim 13, characterized by a stop pin (25) for the free rivet end of the separating knife (8). 15. Isolation switch according to claim 11 or 12, characterized by a compression spring (21) on the angle arm (16) connected to the contact pin (11) of the extinguishing chamber (10), which compression spring (21) rests on the separation knife (8). 16. Disconnector according to one or more of claims 1 to 15, characterized in that the lagging contact (9) is electrically connected to the fixed contact (lia) in the extinguishing chamber (10). 17. Disconnector according to one or more of claims 1 to 16, characterized in that the movable contact pin (11) of the extinguishing chamber (10) is electrically connected to the disconnector pivot point contact (7) via the kinematics (15).