DE3875528T2 - MODULE CIRCUIT BREAKERS, CONSISTING OF A RELEASE BLOCK INTERACTING WITH A MULTIPOLAR CIRCUIT BREAKER BLOCK. - Google Patents

Description

The invention relates to a circuit breaker in modular design with an auxiliary tripping block, in particular a differential or shunt tripping device, for arranging and coupling to a multi-pole circuit breaker block with several switch poles arranged in a row, each of the poles of said circuit breaker block being equipped with separable contacts and a first drive mechanism with which said contacts are actuated either manually via a first actuating lever with two stable switching positions corresponding to the on or off position of the circuit breaker, or in the event of an overload or short circuit automatically via the trip rod controlled by a main tripping device, and said auxiliary tripping block is equipped with an electromagnetic relay which acts on a second drive mechanism with an associated second actuating lever for re-tensioning the tripping block and a first mechanical tripping connection which serves to actuate a pin of the second drive mechanism in a corresponding opening in the insulating housing of the adjacent switch pole to transmit the relay tripping command to the tripping rod.

A residual current release with automatic re-tensioning of the trip block is described in the applicant's document FR-A-2 437 692. The coupling of the residual current block to the circuit breaker block is carried out by the electrician, who must ensure that the trip pin of the trip block is correctly fitted into the first drive mechanism of the adjacent pole and that the operating levers are coupled together in such a way that the trip block is tensioned by actuating the first drive mechanism. If these two conditions are not met, the residual current release does not work. Incorrect coupling can occur if the two operating levers are in different positions, in particular when attempting to couple a relaxed trip block to a tensioned and switched-on circuit breaker block.

Furthermore, residual current circuit breakers are known in which the tripping block is tensioned manually and the entire switching unit becomes inoperable due to a faulty coupling of the two blocks.

The invention is based on the object of ensuring a fault-free coupling of the circuit breaker block and the auxiliary trip block of a modular circuit breaker, regardless of the voltage or tripping state of the blocks.

The circuit breaker according to the invention is characterized in that a slope is formed in the switching mechanism of the first and second actuating levers on the tripping rod of the main tripping device and the pin of the first mechanical tripping connection of the second drive mechanism acts on said slope in such a way that a forced tripping of the circuit breaker block is ensured when the two actuating levers are in different positions, in particular when a relaxed tripping block is coupled to a switched-on circuit breaker block, in that the coupling of the two blocks causes the tripping rod to pivot into the tripped position.

In the event of a faulty connection, the circuit breaker block is automatically brought into a position by its forced tripping that enables the connection of the two blocks.

According to a further development of the invention, the forced tripping of the circuit breaker block caused by the action of the pin on the slope takes place before the coupling of the two actuating levers of the first and second drive mechanisms, since when the pin and the slope come into contact, a preset play remains between the said actuating levers.

The second drive mechanism has a second mechanical connection for re-tensioning the tripping block with a driver which, when the first actuating lever of the first drive mechanism is manually moved to the closed position of the circuit breaker block, moves the second actuating lever to the tensioned position. This second mechanical connection can act in one or two directions.

The two blocks are centered using lugs attached to the trip block, which are inserted into the opposite fitting holes of the adjacent switch pole. The pin of the first mechanical trip connection is shorter than the lugs.

Further advantages will become apparent from the following description of two embodiments of the invention, which are shown in the accompanying drawings as follows:

- Figure 1 shows a schematic representation of the front view of the circuit breaker at the moment of coupling a triggered trip block to a switched-off circuit breaker block, with the first mechanical trip connection shown in the upper enlarged detail and the second mechanical connection for re-tensioning the trip block shown in the lower enlarged detail;

- Figure 2 corresponds to the representation in Figure 1, but with the trip block charged and the circuit breaker block switched off;

- Figure 3 corresponds to the representation in Figure 1, but with the trip block charged and the circuit breaker block switched on;

- Figure 4 corresponds to the representation in Figure 1, but with the trip block triggered and the circuit breaker block switched on;

- Figure 5 shows a partial view of the first drive mechanism of the pole of a circuit breaker block, the mechanism being in the closed position;

- Figure 6 corresponds to the representation in Figure 5, but with the pole position switched off;

- Figure 7 shows a section of an enlarged partial view of the coupling area of the two blocks.

- Figure 8 shows the side view of a detail from Figure 7 at the level of the first mechanical release connection;

- Figure 9 shows a schematic representation of the release rod for coupled blocks arranged in a row.

- Figure 10 shows the schematic partial view of a version variant.

The figures show an auxiliary trip block 12 designed as a differential or shunt trip, which is arranged in series and coupled to a two-pole circuit breaker block 10 to form a circuit breaker with differential current protection or remote operation.

The circuit breaker block consists of two standard poles 14, 16 arranged in series, each equipped with two connection terminals, two separable contacts 18, 20 (Figures 5 and 6) and a first drive mechanism 22 with which the contacts are operated either manually via an operating lever 24 with two stable switching positions corresponding to the closed or open position of the circuit breaker, or automatically in the event of an overload or short circuit by a magnetothermal main release (not shown) which acts on a common release rod 26. The operating levers 24 of the two poles 14, 16 are mechanically connected to one another by a common bar 28. The type of drive mechanism 22 (Figures 5 and 6) of each pole 14, 16 is described in the applicant's European patent application No. 86 402 267 and consists of a trip lever 30 pivoted on a shaft 32 supported by a rotary disc 34, which rotates about a pivot 36 when the circuit breaker is opened or closed. A coupling rod 38 is arranged between the actuating lever 24 and a latch (not shown) mounted on the rotary disc 34, which is released by the trip lever 30 when a fault is detected by the magnetothermal trip device. This trip command can be given by a pivot 44 (Figures 5 and 9) in the form of an auxiliary shaft connecting the arms of the trip levers 30 of both poles to the adjacent pole of the circuit breaker 10. The opposite sides of the insulating housing 40 of each pole are provided with two aligned openings 42 for transmitting the tripping commands between the poles of the circuit breaker block 10 and the tripping block 12. The passing on of a tripping command by a pole always takes place to the left, the receipt of a tripping command from the right (Figure 9).

The circuit breaker block 10 can of course be composed of three protected poles arranged in a row or of one pole and an N-conductor block.

The auxiliary trip block 12 is equipped with an electromagnetic relay 45 which interacts with a second drive mechanism 46 (see Figures 1 to 4). The relay is controlled via a residual current transformer or via a remote control and then transmits the trip command to the adjacent switch pole 10. The drive mechanism 46 of the trip block 12 is connected to the circuit breaker block 10 via a first mechanical trip connection 48 shown in the upper detailed view of Figures 1 to 4 and via a second mechanical connection 50 shown in the lower detailed views for re-tensioning the relay 45 of the trip block 12.

The first mechanical connection 48 transmits the tripping command of the relay 45 to the tripping rod 26 by fitting a pin 52 of the drive mechanism 46 into the opening formed on the right-hand side of the housing of the pole 16. The second mechanical connection 50 of the drive mechanism 46 comprises a tensioning lever 54 equipped with a driver 56, which interacts with the actuating lever 24 of the switch pole 16. The actuating lever 24 of the circuit breaker block 10 drives the tensioning lever 54 of the tripping block 12 in one direction only when the drive mechanism 22 is moved into the closed position. When the circuit breaker is moved into the opposite open position, there is no drive connection between the both operating levers 54, 24.

The re-tensioning of the drive mechanism 46 after triggering the auxiliary trigger block 12 takes place in two phases:

- During the first phase of transmission of the tripping command from the relay 45 via the pin 52 to the trip rod 26, the circuit breaker opens and a charging lever (not shown) of the drive mechanism 46 automatically returns the relay 45 to the charged position. The operating lever 54, however, is in the tripped position and the second mechanical connection 50 is not active.

- During the second phase, the manual movement of the operating lever 24 to the closed position of the circuit breaker 10 activates the second mechanical link 50, by which the operating lever 54 returns to the charged position and the effect of the retaining force of the charging lever of the drive mechanism 46 on the relay 45 is cancelled. The auxiliary trip block 12 can then transmit a new trip command to the circuit breaker block 10.

The lateral coupling of the two mechanical connections 48, 50 between the auxiliary trip block 12 and the circuit breaker block 10 must be carried out without errors. For this purpose, the housing 59 of the auxiliary trip block 12 is provided with extension pieces 60 which must be fitted into the fitting openings 61 in the housing 40 of the pole 16 (Figure 7). The extension pieces 60 and the release pin 52 of the auxiliary release block 12 are parallel to one another and protrude from the inner side surface of the housing 59, whereby the pin 52 is shorter than the extension pieces 60. When the two blocks 10, 12 are arranged side by side, the pin 52 of the first mechanical connection 48 is inserted into the opening 42 on the right-hand side of the pole 16 and interacts with a shoulder 62 or a bevel 64 of the release lever 30 depending on the tensioned or released position of the drive mechanisms 22, 46 of the two blocks 10, 12. The shoulder 62 runs parallel to the release pin 52 and is between the bevel 64 and a blind hole 66 in the Release lever 30 is arranged.

When the operator connects the two blocks 10, 12, two assembly cases can occur:

- When the circuit breaker block 10 is switched off (operating lever 24 in Figures 1 and 2 in position 0), the trip lever 30 of each pole 14, 16 is in the upper position (Figure 6) corresponding to the tripped position of the trip rod 26. The introduction of the trip pin 52 into the pole 16 and the coupling of the operating levers 24, 54 by the driver 56 of the second mechanical connection 50 can be carried out without any problem, regardless of whether the operating lever 54 of the auxiliary trip block 12 is in the tripped position (position 0 in Figure 1) or in the tensioned position (position 1 in Figure 2).

- When the circuit breaker block 10 is switched on (operating lever 24 in Figures 1 and 2 in position 1), the trip lever 30 of each pole 14, 16 is in the lower position (Figure 5) corresponding to the tensioned position of the trip rod 26. When the operating lever 54 of the trip block 12 is in the tensioned position (position 1 in Figure 3), the two blocks 10, 12 can be connected by inserting the trip pin 52 and coupling the operating levers 24, 54. It should be noted that the common bar 28 of the operating levers 24 of the circuit breaker block 10 is arranged below the driver 56 of the operating lever 54 of the auxiliary trip block 12. This arrangement is essential for forming the second mechanical connection 50 for re-tensioning the trip block. If the actuating lever 54 is in the tripped position (position 0 in Figure 4), the actuating levers 24, 54 initially have a different position. The tripping pin 52 of the auxiliary tripping block 12 now acts on the bevel 64 (see Figures 7 and 8), so that the tripping lever 30 and the tripping rod 26 are moved to the tripped position, which results in the circuit breaker block 10 being switched off. This rotary movement, which causes a forced trip, results from the pushing movement of the pin 52 against the bevel 64 when the two blocks are joined together. The forced tripping takes place before the coupling of the two actuating levers 24, 54, since when the pin 52 and the bevel 64 touch, a preset clearance J (see Figure 7) remains between the said actuating levers. After the forced tripping, the assembly situation corresponds to Figure 1, and the coupling of the two blocks 10, 12 is possible without any problems. The actuating lever 24 of the circuit breaker block 10 is arranged below the actuating lever 54 of the tripping block 12 in order to establish the second mechanical connection 50. Closing the contacts of the circuit breaker block 10 by manually moving the actuating lever 24 to the switch position I (Figure 5) causes the actuating lever 54 to be driven along and transferred to the tensioned position of the auxiliary tripping block 12.

The second mechanical connection 50 can of course also be bidirectional by a fixed connection of the driver 56 to the actuating levers 24, 54 of the two blocks 10, 12 arranged in a row. The drive mechanism 46 of the trip block 12 would then be changed so that the tensioning movement for the relay 45 is provided by the switching-off movement of the circuit breaker.

The second mechanical connection 50 could also be omitted entirely, in which case the auxiliary trip block 12 would be re-tensioned manually by turning the operating lever 54 before the circuit breaker 10 is switched on.

In both design variants, the forced tripping of the circuit breaker block 10 is ensured by the effect of the tripping pin 52 on the slope 64 if the operator connects a relaxed tripping block 12 to a tensioned circuit breaker block 10.

Figure 9 shows a schematic representation of the transmission of the tripping movement between the tripping block 12 and the poles 14, 16 of the circuit breaker block 10. The tripping rod 26 is modular and is created by the interaction of the transversely arranged tripping pins 52, 44 and tripping lever 30 of the switch poles 16, 14. The tripping rod 26 of the circuit breaker serves for multi-pole triggering between poles 14, 16 and for triggering by auxiliary block 12. The modular disassembly of trigger shaft 12 enables different movements to be carried out in blocks 10 and 12. When connecting the pole blocks, pin 44 for connecting the trigger levers 30 of the two poles 14, 16 extends completely into blind bore 66 in trigger lever 30 of pole 14 and is guided by it. The other end of pin 44 extends into a bore in trigger lever 30 of pole 16. This bidirectional connection enables the triggering movement to be transmitted in both directions, ie from pole 14 to pole 16 and vice versa. The connection to the auxiliary trip block 12 is only effective in one direction, since the trip pin 52 of the drive mechanism 46 does not protrude into the blind hole 66 in the trip lever 30 of the pole 16, but only interacts with the shoulder 62 in one direction of rotation of the trip rod 26. The tripping movement is only transmitted to the left, ie from the trip block 12 to the switch pole 16, but not in the opposite direction. The shutdown of the circuit breaker 10 in the event of an overload or short circuit does not result in the auxiliary block 12 being tripped.

The release pin 52 of the auxiliary release block 12 is inserted into the adjacent pole 16 directly, without the use of intermediate elements, since the pin 52 is part of the first mechanical connection 48 integrated into the drive mechanism 46.

In the variant according to Figure 10, no forced release is provided for when the operating levers 24, 54 are in different positions, but the operating lever 54 of the trip block 12 is automatically reset using a latch 70. This latch is advantageously integrated into the driver 56 of the operating lever 54. When a switched-on circuit breaker block 10 is coupled to a relaxed trip block 12, the latch 70 causes the operating lever 54 to pivot into the tensioned position, i.e. into a position analogous to that of the operating lever 24.

Claims (8)

1. Circuit breaker in modular design with auxiliary tripping block (12), in particular a differential or shunt tripping device, for arranging and coupling to a multi-pole circuit breaker block (10) with several switch poles arranged in series, each of the poles of said circuit breaker block (10) being equipped with separable contacts (18, 20) and a first drive mechanism (22) with which said contacts are actuated either manually via a first actuating lever (24) with two stable switching positions corresponding to the on or off position of the circuit breaker, or in the event of an overload or short circuit automatically via the tripping rod (26) controlled by a main tripping device, and said auxiliary tripping block (12) is equipped with an electromagnetic relay (45) which is connected to a second drive mechanism (46) with an associated second actuating lever (54) for re-tensioning the trip block (12) and a first mechanical trip connection (48) which serves to transmit the trip command of the relay (45) to the trip rod (26) by fitting a pin (52) of the second drive mechanism (46) into a corresponding opening (42) in the insulating housing (40) of the adjacent switch pole (16), characterized in that a slope (64) is formed in the switching mechanism of the first and second actuating levers (24, 54) on the trip rod (26) of the main trip and the pin (52) of the first mechanical trip connection (48) of the second drive mechanism (46) acts on said slope (64) in such a way that forced tripping of the circuit breaker block (10) is ensured when the two actuating levers (24, 54) are in different positions, in particular when a relaxed trip block (12) is coupled to a switched-on circuit breaker block (10), in that the coupling of the two blocks (10, 12) causes the trip rod (26) to pivot into the tripped position. 2. Circuit breaker in modular design according to claim 1, characterized in that the action of the pin (52) on the The forced tripping of the circuit breaker block (10) caused by the bevel (64) takes place before the coupling of the two operating levers (24, 54) of the first and the second drive mechanism (22, 46), since when the pin (52) and the bevel (64) come into contact, a preset clearance J remains between the said operating levers. 3. Circuit breaker in modular design according to claim 2, characterized in that the second drive mechanism (46) has a second mechanical connection (50) serving to re-tension the trip block (12) with a driver (56) which, when the first actuating lever (24) of the first drive mechanism (22) is manually moved to the switched-on position of the circuit breaker block (10), transfers the second actuating lever (54) to the tensioned position. 4. Circuit breaker in modular design according to claim 3, characterized in that the second mechanical connection (50) for re-tensioning the trip block (12) by attaching the driver (56) to the second actuating lever (54) only acts in one direction, such that the driver (56) is only carried along by the first actuating lever (24) of the first drive mechanism (22) during the closing stroke. 5. Circuit breaker in modular design according to claim 3, characterized in that the second mechanical connection (50) for re-tensioning the trip block (12) acts bidirectionally by directly connecting the driver (56) to both actuating levers (24, 54), the second drive mechanism (46) being designed in such a way that the tensioning movement for the relay (45) of the trip block (12) is provided by the switching-off stroke of the first drive mechanism (22). 6. Modular circuit breaker according to one of claims 1 to 5, characterized in that the tripping block (12) is provided with extension pieces (60) for receiving through the opposite fitting openings (61) of the switch pole (16) in order to center the two blocks (10, 12) arranged next to one another, the Extension pieces (60) and the pin (52) of the second mechanical release connection (48) protrude from the inside of the release block (12) and are arranged parallel to each other. 7. Circuit breaker in modular design according to claim 6, characterized in that the pin (52) of the first mechanical tripping connection (48) is shorter than the extension pieces (60). 8. Circuit breaker in modular design according to one of claims 1 to 7, characterized in that the slope (64) for transmitting force to the trip rod (26) is located directly on the trip lever (30) of the first drive mechanism (22) of the switch pole (16) that borders on the trip block (12).