EP0563530B1 - Power switch block - Google Patents

Abstract

A power connecting block consists of a housing (1) having a lower part and side walls attached thereto, and having connections for busbars, of a switching cage (7) which can move transversely with respect to the longitudinal axis of the housing (1) and has fuse inserts (which are arranged thereon) and guide webs (9), and of a switching lever (11) having connecting elements (14, 15) which are arranged at a distance from one another and are guided in the side walls of the housing (1) by means of complementary parts (16, 17). In order that only a small amount of space is required when the block is in the switched-off state, and in order that low operating forces on the switching lever are nevertheless achieved, it is provided according to the invention that one connecting element on the rigid, mechanical switching lever (11) is constructed as a rotating journal (15) which is guided in an elongated hole (16), and that the other connecting element on the switching lever (11) is constructed as a bearing journal (14) which is guided in an elongated recess (17), which is arranged at a distance from the elongated hole (16), is parallel thereto and is open to the outside towards the upper edge (37), on the switching-lever side, of the housing, and has a bearing pocket (36) at the opposite, inner end in order to support the bearing journal (14) on the switching lever (11) in a force-fitting manner, and in that a bent free-running link (32) is provided between the bearing pocket (36) and the upper edge (37) of the housing (1). <IMAGE>

Description

The invention relates to a power switch, consisting of a housing with a lower part and side walls attached to it and with connections for busbars, from a switching cage movable relative to the housing, transversely to its longitudinal axis, with fuse inserts and guide bars arranged thereon, and from a rigid mechanical switching lever with a spacing mutually arranged connecting elements which are guided by means of complementary parts in the side walls of the housing, of which the one connecting element on the shift lever is designed as a pivot which is guided in a slot as a complementary part in the side wall and of which the other connecting element on the shift lever as Bearing pin is formed, which is arranged in a spaced from the elongated hole and essentially parallel to this, elongated recess as a complementary part in the side wall, the elongated recess after is open to the upper edge of the housing on the lever side, and has a bearing pocket at the opposite inner end for non-positive support of the bearing pin on the switching lever. (EP-A-0 199 182).

NH fuse-links are switched with such known load-switching strips, and for this purpose they are used in low-voltage distributions of energy supply companies in industrial companies and large buildings. In addition to protecting the connected electrical circuits, these devices also have the task of isolating certain systems or power supplies from a power supply via a safe isolating path during inspection work.

Known NH fuse switchgear are installed in control cabinets. Operating elements are accessible from the outside through appropriate front cutouts, or they can be covered behind closed doors. In accordance with the safety regulations for work on electrical systems, the switching device must be secured against unauthorized switching on. In known industrial systems, this is done in such a way that the device is blocked in the disconnected position by up to three padlocks. These padlocks can only be removed by those who carry out work on the activated systems. Securing against restarting can also be done by locking the switch cabinet in which the switchgear is located.

It is easy to see that the depth of the switchgear in the disconnected position strongly influences the cabinet depth in such cases. Also in control cabinets where the controls accessible from the outside, the depth of the switchgear in the disconnected position is an important design feature, since device parts that protrude too far into the operating aisle in front of the control cabinets can have a disruptive or even accident-causing effect.

In a known NH fuse switch disconnector, three fuse links are switched simultaneously, which requires larger switching forces. Correspondingly lower actuation forces are achieved in the known power switch strip by means of a long switch lever. Since this, like the fuse cover and the NH fuse links, protrudes approximately at right angles from the strip body in the disconnected position, this arrangement results in a very large and correspondingly unfavorable overall depth. For this reason, it is provided in the known strip that the shift lever can be inserted telescopically, thereby reducing the overall depth in the disconnected position. At the same time, the inserted shift lever, the lower end of which dips into the last body, blocks the device in the disconnected position. However, this known power switch has the disadvantage that despite these measures, a considerable depth is still required in the disconnected position, the NH fuse links and possibly other active parts are easily accessible to unauthorized persons, and the selected telescopic construction of the switch lever is very expensive and mechanically unstable.

The invention is therefore based on the object to provide a power switch of the type mentioned, in which an even smaller space requirement is achieved in the switched-off state and nevertheless low actuating forces are achieved on the shift lever, although at least two fuse links can be switched simultaneously with this strip.

This object is achieved in that a curved free-wheel link is provided between the bearing pocket and the upper edge of the housing.

According to the invention, a rigid, mechanical, integral switching lever is used, which is long enough to achieve low switching forces, but which, when not in use, namely in its rest or parking position, is arranged parallel to the housing, so that the entire switching strip is both in the on as well as in the off state only requires a relatively small installation depth. Due to the mechanical, one-piece design of the shift lever, even if it is made of plastic for safety reasons, great rigidity and mechanical strength is achieved, so that the switching takes place reliably for the user. The person skilled in the art recognizes the stability of the safety edge according to the invention particularly from the one-piece, strong plastic lever, in which no joints and no parts which are movable relative to one another are permitted.

By means of the measures according to the invention, the switching cage is moved with the aid of this one-piece switching lever by means of pivot pins and bearing pins from the operating position into the disconnected position, in which the switching cage moves substantially perpendicularly to the longitudinal axis of the housing and approximately parallel to the slot mentioned to the front away from the mounting plane ( into the disconnected position) or back to the level (closed position).

While similar movements of the switch cage from the operating position away from the housing into the disconnected position are also carried out in the case of smaller switches, the construction depth can be achieved when using the power switch strip according to the invention by moving from the disconnected position into an additional position, which is also an open position and at which is achieved in the elongated recess by the curved free-wheel backdrop free-running of the bearing pin. Due to the free-wheeling linkage according to the invention, the elongated recess is created so large that the bearing pin on the shift lever disengages from the housing wall and pivoting of the shift lever into the parking position is possible, in which the shift lever is approximately parallel to the longitudinal axis of the housing. This shifting of the shift lever in parallel position with the advantage of the ultimately small overall depth is achieved by shifting the pivot point of the shift lever from the bearing pin located in the freewheel area to the pivot pin in the end position in the elongated hole.

In the new invention, when the load switch strip is opened, the switching cage, based on the housing, can be pulled out from the first operating position via the second off position into the third additional position, and in this third additional position the rigid long switching lever can be moved via the freewheeling movement of the Bearing pin are brought into a parking position, in which the shift lever is parallel to the longitudinal axis of the housing with the advantage of the small depth due to the compact design.

There is a boundary between the storage pocket and the freewheel link, which corresponds to the transition between the second off position and the third additional position.

For example, if a user only wants to replace fuse links and does not get into the third additional position, an inexperienced user may inadvertently reach the third additional position when opening from the first operating position due to the momentum of the switching movement via the second off position . In order to avoid such cases and to improve the operation even for inexperienced users, the invention further provides that a locking unit with movable keys and locking lugs is articulated on the switching cage in such a way that the locking lugs engage with the respective side wall of the housing can be brought and preferably the shift lever can be locked in its parking position approximately parallel to the longitudinal axis of the housing with the locking unit.

By means of this locking unit provided according to the invention on the switch cage, a lock can be provided both in the closed and in the open position of the switch cage, with the result that the user does not switch into the disconnected position or into the closed position without authorization. This provides the option of moving from the disconnected position, e.g. if a machine has been switched off to prevent accidental restart, for example in order to prevent risk of injury to a worker working on the machine. Despite the shallow depth of the switching strip according to the invention, the switching lever can also be locked and locked in the park position corresponding to the disconnected position. If the buttons on the locking unit are configured appropriately, their operation can also be prevented in the open state.

For this purpose, it is particularly expedient if, according to the invention, the locking unit is plate-shaped, lies flat next to a phase partition of the switching cage, is articulated via pivot points on this phase partition and has two opposite latching lugs and buttons. This allows a particularly effective locking of a relative movement between the switching cage and the housing, because the phase partition connects the two parallel side walls of the housing, and the two locking lugs engage in stops in each of the side walls, so that there is no undesired tilting in one direction it is possible to overcome the locking.

Only without the locks mentioned can a user press the buttons and thus the locking lugs so that unauthorized persons cannot switch the power switch.

It is also expedient according to the invention if each of the keys which can be pivoted relative to one another and each of the latching lugs projecting outward from a deflection lever is articulated at an extra pivot point. This results in good kinematics for the locking unit with symmetrical movements and reliable movement of the locking lugs when the buttons are pressed.

So if the user wants to switch the safety edge from the first closed operating position to the third additional open position, then he first comes to the second off position, must then consciously actuate the locking unit, which previously served as a lock in order to provide the possibility by unlocking to move the switch cage to the third additional position.

Conversely, if the user wants to switch the safety edge from the park position into the operating position, he must first unlock the latches again using the buttons on the locking unit and, together with this conscious activity, ensure that the bearing journal is properly inserted into the bearing pocket along the free-wheeling backdrop. so that the fulcrum for the shift lever shifts again from the mentioned pivot to the bearing pin. The locking unit thus advantageously prevents an undesired shifting of the switching cage from the second off position into the additional parking position and acts as a defined lock during the transition from the aforementioned second position into the third position without actuation of the locking lugs. Conversely, the locking device ensures when switching on that the switch cage can only be moved into the operating position when the latch is deliberately unlocked.

It has been shown that it is particularly advantageous if, according to the invention, each key and each deflecting lever with locking lug is connected to a yoke arranged in the central region of the plate-shaped locking unit via a respective tie bar. Such a locking unit can be actuated easily and with low forces, but these forces are nevertheless sufficient to pull out the catches of stops on the side walls of the housing practically perpendicular to these side walls; even with a stronger contact pressure, if frictional forces could counteract such a pulling movement. The locking lugs can be designed so that they can be secured at different points in the locked position, so that practically the position of the switch cage can be locked outside or inside. The plate-shaped locking unit can be produced as a one-piece molded part, but also as a stamped part, preferably made of plastic.

Expediently, for example, there may be holes in the buttons in the area facing outward from the fastening level of the strip in the control cabinet, which can then be brought very close to the shift lever when the shift lever is brought into the parking position parallel to the housing. Locking unit and shift lever can then be designed so that a crossbar attached to the shift lever has a recess which comes to lie in the parking position close to the hole in the button of the locking unit, so that a padlock can be easily passed through both holes. This assignment of the shift lever and locking unit prevents the shift cage from moving from the operating position (switch-on state) to the disconnected position (switch-off state) and / or vice versa.

In a further embodiment of the invention, a guide groove extending approximately perpendicular to its longitudinal axis is provided in the respective side wall of the housing and is interrupted by a stop. This guide groove runs approximately parallel to that mentioned at the beginning Elongated hole for the pivot pin, ie the groove extends in the direction transverse to the longitudinal and transverse axes of the housing, ie perpendicularly from the mounting level for the safety edge in the direction of the device depth. In this direction, the shift cage can be pulled out or pushed in substantially in a straight line relative to the housing, these actuating forces being applied with the aid of the shift lever. In the direction thus explained, at least one guide groove extends into each of the side walls, because corresponding, complementarily designed guide webs can slide in these guide grooves on the switch cage, so that the relative movement between the switch cage and the housing can take place with the aid of these guide elements. The abovementioned stop in the guide groove ensures that locking lugs of the locking unit are stopped at certain points in such a way that the switch cage strikes the position at certain positions with respect to the housing. Only when the locking lugs are disengaged from the stops by actuating the buttons can the switching cage move further with respect to the housing.

According to a further advantageous embodiment of the invention, the elongated hole and the elongated recess in the side wall of the housing run essentially parallel to the groove for the latching lugs, and the elongated hole is arranged at a distance between the elongated recess and the groove. The shift lever carries the inside of the already mentioned bearing journal, the "long lever" of the shift lever being between the outer handle part and this bearing journal, to which the "short lever" of the shift lever lies at an angle, namely on the route between the bearing journal and the Above-mentioned pivot pin on the shift lever, via which the shift cage is lifted out or pushed in relative to the housing when the shift lever is actuated. In such a configuration of the shift lever, it can be seen that strong forces are exerted on the bearing wall via the bearing journal, and for this purpose the bearing pocket at the inner end of the elongated recess is used, namely for the frictional support of the bearing journal. Most distant from this bearing pocket is the guide groove, in which the locking lugs and thus the locking unit is guided, so that when closing between the crossbar of the shift lever on the one hand and the locking unit on the other hand a relatively large lever is provided to ensure the locking forces. This ensures that the lock is secure and you can see that the entire construction of the safety edge is robust and the strength of the parts is great.

According to the invention, in a further advantageous embodiment, it is further provided that outside of the articulation area of the shift lever, viewed in the direction of the longitudinal axis of the housing, pairs of guide webs extending parallel to the elongated hole are attached on both sides, at least one of which is provided with a spring-loaded support which is provided with the actuating cam can be brought into engagement on the cheek of the shift lever. In the respective side wall of the housing there is preferably not only one but, at a distance from one another on both sides of the articulation region of the shift lever, guide grooves are provided which run perpendicular to the fastening plane and in which the guide webs of the shift cage can slide. Correspondingly, two guide webs or, in a correspondingly different embodiment, two pairs of guide webs are also attached to each transverse side of the switching cage, the locking unit being mounted in the region of the one guide web or pair of guide webs and the device with the spring support at a distance therefrom on the other guide web or pair of guide webs is provided. This arrangement distributes the forces acting on the switch cage. If one had only the guide groove with the stop for the locking by the locking lugs of the locking unit, the locking would be asymmetrical against pulling out and pushing in of the switching cage, so that tilting of the switching cage in one direction or the other would not be excluded. Due to the advantageous arrangement of the other guide groove in the respective side wall of the housing, into which, for example, a guide web can slide in, the supporting forces are symmetrized in the event of unauthorized or unintentional switching on or attempted switching off. The outer, that is to say the upper edge of the housing arranged on the shift lever, stands like a stop of the spring support and thereby prevents the shifting cage from moving relative to the housing. The spring support can be actuated from the locking position into the unlocking position and vice versa with the aid of an actuating cam which is formed on the cheek of the shift lever. This is a projection that slides past the outer edge of the spring support when the switching lever is actuated so that the spring support is pressed into the guide web in such a way that the guide web can slide in the guide groove without a locking effect. This is the unlocked position of the spring support. If the actuating cam disengages from the spring support by turning the switching lever further, it jumps out over the outer contour of the guide web, to which it is attached, in such a way that it returns to the locking position or slides against the guide groove so that it jumps outwards can, as soon as the guide bar with its spring support is pulled out of the guide groove over the upper edge. Pushing back is then no longer possible.

The advantage of the spring support lies in the increased ease of use by creating defined conditions. The movement of the shift cage from the park position towards the operating position is only possible if the actuating cam on the cheek of the shift lever has come into engagement with the spring support, and this only succeeds when the shift lever is swiveled up in such a way that the inner bearing journal is located at the opposite end is guided over the freewheel link until it reaches the area of the bearing shell.

But this is precisely how the defined conditions are created so that the rotation is shifted back from the pivot pin back to the bearing pin. By observing these defined conditions, one avoids jamming or blocking the actuation, in particular in the case of inexperienced users. It should be noted that only correct operating movements can inevitably be carried out if the power switch strip has both the locking device and the spring support.

It can thus be seen that measures are provided by the construction of the load-switching strip which has been redesigned in accordance with the invention, that robust and reliable switching means are nevertheless provided in the switched-off state even with a small space requirement of the strip and that locking measures are also possible in order to prevent the switching cage from tilting in different positions lock inoperable relative to the housing.

Figur 1

die Seitenansicht des Gehäuses mit Schalthebel in Parallelstellung in der Betriebsposition (eingeschaltet),

Figur 2

eine ähnliche Ansicht wie Figur 1, wobei jedoch der Schaltkäfig durch Betätigen des Schalthebels in die Trannstellung aus dem Gehäuse herausgezogen ist,

Figur 3

eine weitere ähnliche Ansicht wie Figur 2, wobei jedoch der Schaltkäfig über die Stellung der Figur 2 hinaus in die ausgeschaltete Ruheposition gezogen ist, mit verriegelter Parallelstellung des Schalthebels mit strichpunktierten Linien,

Figur 4

eine Querschnittsansicht entlang der Linie A-A in Figur 2,

Figur 5

eine abgebrochene Einzelheit der Verriegelungseinheit entsprechend dem Kreis Z in Figur 4,

Figur 6

eine ähnliche Darstellung wie Figur 5, wobei jedoch die Rastnase in der entriegelten Position gezeigt ist,

Figur 7

eine ähnliche Ansicht wie Figur 5 oder 6, wobei die Rastnase in einer gegenüber der Stellung in Figur 5 anderen Verriegelungsposition eingerastet gezeigt ist,

Figur 8

eine abgebrochene Einzelheit entsprechend dem Kreis Z in Figur 3 unter Darstellung der Federstütze in Entriegelungsstellung,

Figur 9

eine ähnliche Darstellung wie Figur 8, bei welcher die Federstütze aber in die Verriegelungsstellung aufgesprungen dargestellt ist,

Figur 10

eine weitere ähnliche Darstellung wie in den Figuren 8 und 9, jedoch mit der Federstütze in der Führungsnut,

Figur 11

eine Draufsicht auf die Lastschaltleiste, wenn man in Figur 1 von rechts nach links auf die Befestigungsebene blickt, und

Figur 12

eine abgebrochene Einzelheit entsprechend dem Kreis X in Figur 11.

Further advantages, features and possible uses of the present invention result from the following description of a preferred exemplary embodiment in conjunction with the attached drawings. Show it:

Figure 1

the side view of the housing with the shift lever in the parallel position in the operating position (switched on),

Figure 2

1 a view similar to FIG. 1, but with the switching cage being pulled out of the housing into the tripping position by actuating the switching lever,

Figure 3

2 shows a further view similar to FIG. 2, but with the shift cage pulled beyond the position of FIG. 2 into the deactivated rest position, with the shift lever locked in parallel position with dash-dotted lines,

Figure 4

3 shows a cross-sectional view along the line AA in FIG. 2,

Figure 5

4 shows a broken-off detail of the locking unit corresponding to the circle Z in FIG. 4,

Figure 6

5 shows a representation similar to that of FIG. 5, but showing the latch in the unlocked position,

Figure 7

5 shows a view similar to FIG. 5 or 6, the latching nose being shown locked in a different locking position from the position in FIG. 5,

Figure 8

3 shows a broken-off detail corresponding to the circle Z in FIG. 3, showing the spring support in the unlocked position,

Figure 9

8 shows a representation similar to that in FIG. 8, in which the spring support is shown in the locked position,

Figure 10

another similar representation as in Figures 8 and 9, but with the Spring support in the guide groove,

Figure 11

a plan view of the power switch, if you look in Figure 1 from right to left on the mounting level, and

Figure 12

an interrupted detail corresponding to the circle X in Figure 11.

The embodiment shown here is an NH fuse-switch disconnector, the fastening plane of which, as shown in FIG. 11, is the paper plane and, according to FIGS. 1 to 3, runs perpendicular to the paper plane through the left edge of the housing 1, the longitudinal axis 2 of which is shown in broken lines in FIG is. This is parallel to the mounting plane and perpendicular to the transverse direction 3 of the housing 1, which can be seen in broken lines in FIG. In the cross section of FIG. 11 it can be seen that the housing has a lower part 4 and on this outside two side walls 5, 5 ′, so that in cross section along the line AA in FIG. 2 there is essentially the shape of a U for the housing 1 (Figure 4).

Connections 6 for current busbars, not shown, which are electrically connected to fuse inserts, not shown, are of course also provided on the housing 1.

Separately from the housing 1, the switching strip also has the switching cage 7 with fuse inserts attached to it, one phase partition 7 'of which can be seen in FIG. In the direction of the longitudinal axis 2 of the housing 1, guide grooves 8 are provided in each of the side walls 5 and 5 'of the housing, which separate the side walls 5 and 5' in the longitudinal direction 2 into three thirds surfaces, with the representation in FIGS. 1 to 3 and 11, the top third at the top and the bottom third at the bottom is to be thought. In these guide grooves 8, guide webs 9 fastened to the switch cage 7, which divide the switch cage 7 in a corresponding manner, seen in the longitudinal direction, into three thirds. In this embodiment, there are two pairs of guide webs 9, which are fastened to the switch cage and extend in the pulling or sliding direction 10 perpendicularly to the fastening plane (drawing plane of FIG. 11).

Finally, the power switch strip also has a shift lever 11 which has cheeks 12 and a crossbar 13 in its inner region. At its inner end opposite the outer gripping end there are bearing pins 14 and pivot pins 15 arranged at a distance (small lever) therefrom. The pivot pins 15 are received in an elongated hole 16, while the bearing pins 14 are guided in an elongated recess 17 parallel to the elongated hole 16.

A locking unit 18 is articulated on the switching cage 7, which can be seen most clearly from FIG. 4. The shape of the locking unit 18 is plate-shaped, as can also be seen from the figure 12 sees. In the middle, it has a yoke 19, on which 20 keys 21 are articulated upwards and outwards via webs which, when actuated for unlocking in the direction of arrows 22 (FIG. 4), can be moved towards one another in such a way that they move around the pivot points 23 turn. As a result, the yoke 19 moves in the upward direction 10 upwards, with the result that the deflection levers 25 articulated on the yoke 19 via further tie bars 24 with outwardly projecting locking lugs 26 pivot about the pivot points 27 in such a way that the deflection levers 25 with the locking lugs 26 in Direction of arrows 28 - that is, in the unlocked position. The articulation of the plate-shaped locking unit 18 flat next to the phase dividing wall 7 'of the switching cage 7, namely the articulation via the pivot points 23 and 27 on this phase dividing wall 7', can be seen clearly from the illustration in FIG.

The purpose of the locking unit 18 is to engage or detach the locking lugs 26, which extend on both sides to the side walls 5, 5 'of the housing 1, with these side walls 5, 5', namely to Switch cage 7 to be able to move relative to the housing 1 or not. FIGS. 5 to 7 are expediently considered for this purpose. In this detail broken off according to circle Z in FIG. 4, the guide groove 8 can be seen in the respective side wall 5 of the housing 1, which is interrupted at a certain point by a stop 29. If you open the padlock 30 (Figure 1) so that the shift lever 11 is detachable from the shift cage 7 and the housing 1, then you can pull the shift lever 11 upwards in the direction of the double arrow 31 (Figure 2) to the bottom right of the shift cage 7 pull out of the lowered operating position of FIG. 1 into the position of FIG. 2 until the detent 26 has approached the stop 29 from below, according to FIG. 5 from the left. If you now want to move the shift lever 11 into the parking position, the locking unit 18 is actuated by pressing according to arrows 22, the latch 26 is disengaged from the stop 29, as shown in FIG. 6, and the shift cage 7 together with the shift lever 11 can still be turned a small piece from the position in FIG. 2 into that in FIG. 3 to the right in the direction of arrow 10. After releasing the keys 21 of the locking unit 18, the latches 26 snap into the guide groove 8 above the stop 29 as shown in FIG. 7. The switch cage 7 is now locked against unintentional reconnection.

In this position in FIG. 3 (solid lines), the shift lever 11 can be brought into the park position, which is shown in FIG. 3 with dash-dotted lines. The shift lever 11 now rotates around the pivot pin 15 at the upper right outer end of the straight elongated hole 16, while the bearing pin 14 moves via a curved free-wheel link 32 into the position 14 ′ shown in broken lines. There, the journal 14 is completely from the elongated recess 17 out of engagement. Now the padlock 30 can be put on again, so that unauthorized persons can no longer operate the shift lever 11.

From Figures 3 and 8 to 10 an additional locking against restart is shown. The upper guide web 9 has a recess 33, so that a spring support 34 results. This comes into engagement with the actuating cam 35 on the cheek 12 of the shift lever 11 as shown in FIG. 8, the spring support 34 being pressed within the region of the outer contour of the guide web 9 in order to reach the position in FIG. 8. In this state, the guide web 9 can be pushed into the guide groove 8 to the left, i.e. you can push the switch cage 7 down into the housing 1. The shift lever 11 has reached its position in FIG. 3, from which the bearing pin 14 in the elongated recess 17 reaches down to the bottom left into the inside bottom of the elongated recess 17. Thereafter, the shift lever 11 is turned back to reach the parking position, the bearing pin 14 coming into a bearing pocket 36, namely from the illustration in FIG. 2 into that of FIG. 1. The shift lever 11 has been turned in the direction of the double arrow upward to the left inside 31 reaches the position of FIG. 1, then the actuating cam 35 has left the spring support 34, and this could spring open, but is held by the side walls of the guide groove 8.

When this movement is reversed, ie when the switching cage 7 is pulled out of the housing 1, the spring support 34 can spring open into the position in FIG. 9 after the state in FIG. 3 has been reached, that is to say the switching cage 7 has been pulled out into its outermost position. If in this position of FIG. 3 the switching lever 11 is switched to the parking position shown there in dash-dotted lines, namely parallel to the housing 1, then the actuating cam 35 has also left the spring support 34 again, and this springs open for locking (FIG. 9). If the switch cage 7 is now pressed unintentionally or unauthorized from the outside to bring it back into the operating position (switched on), then the catch 26 supports on the one hand according to the position in FIG. 7 via the stop 29 and on the other hand the spring support 34 via the upper edge 37 on the switch lever side of the housing 1 from the switch cage 7. Protection against unauthorized restarting is avoided without tilting.

Reference list

1

casing

2nd

Longitudinal axis

3rd

Cross direction

4th

Lower part

5, 5 '

Side walls

6

connections

7

Switch cage

7 '

Phase partition

8th

Guide grooves

9

Guide bars

10th

Pull or push direction

11

Gear lever

12th

Cheeks

13

Crossbar

14

Bearing journal

15

Pivot

16

Long hole

17th

Recess

18th

Locking unit

19th

yoke

20th

Docks

21

Keys

22

Arrows

23

Pivot points

24th

Docks

25th

Bell crank

26

Latches

27

Pivot points

28

Arrows

29

attack

30th

Padlock

31

Double arrow

32

Freewheeling backdrop

14 '

position

33

Recess

34

Spring support

35

Actuating cams

36

Storage bag

37

Top edge

Claims (8)

1. A load switching block comprising a housing (1) with a bottom portion (4) and side walls (5, 5') secured thereto and with connections for current bus bars, a switching cage (7) which is movable relative to the housing (1) transversely to its longitudinal axis (2) and with, arranged thereon, fuse cartridges and guide limbs (9), and a rigid mechanical switching lever (11) with connecting elements (14, 15) which are arranged at a spacing from each other and which are guided by means of complementary portions (16, 17) in the side walls (5, 5') of the housing (1), of which the one connecting element on the switching lever (11) is in the form of a rotary trunnion (15) which is guided in a slot (16) as a complementary portion in the side wall (5, 5') and of which the other connecting element on the switching lever (11) is in the form of a mounting trunnion (14) which is guided in an elongate opening (17), as a complementary portion, in the side wall (5, 5'), which opening is arranged at a spacing from and is substantially parallel to the slot (16), wherein the elongate opening (17) is open outwardly to the top edge (37) of the housing (1), at the switching lever side, and at the opposite inner end has a mounting pocket (36) for force-lockingly supporting the mounting trunnion (14) on the switching lever (11), characterised in that a curved free-motion sliding guide (32) is provided between the mounting pocket (36) and the top edge (37) of the housing (1).
2. A load switching block according to claim 1 characterised in that a locking unit (18) with movable buttons (21) and retaining projections (26) is pivoted to the switching cage (7) in such a way that the retaining projections (26) can be brought into retaining engagement with the respective side wall (5, 5') of the housing (1) and preferably the switching lever (11) can be locked in its parked position approximately parallel to the longitudinal axis (2) of the housing (1) by the locking unit (18).
3. A load switching block according to claim 1 or claim 2 characterised in that the locking unit (18) is of a plate-like configuration and, disposed flat beside a phase separation wall (7') of the switching cage (7), is pivoted by way of pivots (23, 27) to said phase separation wall (7') and has two oppositely disposed retaining projections (26) and buttons (21).
4. A load switching block according to one of claims 1 to 3 characterised in that each of the buttons (21) which are pivotable relative to each other and each of the retaining projections (26) which project outwardly from a shift lever is pivoted to an extra pivot (23, 27).
5. A load switching block according to one of claims 1 to 4 characterised in that each button (21) and each shift lever (25) with retaining projection (26) is connected by way of a respective pull limb (20, 24) to a yoke (19) arranged in the central region of the plate-like locking unit (18) (Figure 4).
6. A load switching block according to one of claims 1 to 5 characterised in that disposed in the respective side wall (5, 5') of the housing (1) is a groove (8) which extends approximately perpendicularly to its longitudinal axis (2) and which is interrupted by an abutment (29).
7. A load switching block according to one of claims 1 to 6 characterised in that the slot (16) and the elongate opening (17) in the side wall (5, 5') of the housing (1) extend substantially parallel to the groove (8) for the retaining projections (26) and that the slot (16) is arranged in the spacing between the elongate opening (17) and the groove (8).
8. A load switching block according to one of claims 1 to 7 characterised in that disposed outside the mounting region of the switching lever (11), as viewed in the direction of the longitudinal axis (2) of the housing (1), on both sides, are pairs of guide limbs (9) which extend parallel to the slot (16) and of which at least one is provided with a spring support (34) which can be brought into engagement with the actuating cam (35) on the side plate portion (12) of the switching lever (11).

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