DE202004016746U1 - Bus voltage system for control unit e.g. transformer, has connecting plug provided between bus bars of base and expansion modules, and additional discharging terminal integrated in another connecting plug - Google Patents

Abstract

The system has a base module (31) with an integrated bus bar for a control unit which is regulated over a supply terminal for electrical supply of the bar. The module has an expansion module (32) which has an integrate bus bar for an additional control unit. A connecting plug (1) is provided between the bus bars for their electrical contact, and an additional discharging terminal (27) is integrated in another connecting plug (2).

Description

Busbar system for switchgear with modules, the above Connecting plug with attached output terminal are electrically contacted

From the DE 101 56 214 is a multi-phase busbar system for powering several switching devices known. The system has busbar blocks which are electrically connectable by means of multi-pin connector. These are advantageously designed as a double lyra connector with at least four lyre contacts per phase. Advantageously, the busbar blocks are each held by a mounting base, which serves for the mechanical adaptation of several switching devices.

At the time of the DE 101 56 214 known arrangement, the busbar blocks together with each associated mounting base assembly fields for holding preferably parallel adjacent switching devices ready. The multi-pin connector is designed so flat that it does not protrude at a coupling of two adjacent busbar blocks. The assembly fields of the coupled busbar blocks can therefore be densely populated with switching devices that can be placed directly next to each other.

one huge In practice, technical equipment often needs a large number of electrical switching devices Different types are assigned to all necessary switching and protection functions To run to be able to. To interconnect these properly to be able to Be advantageous busbar systems of the above type used. In this case, switching devices are usually used whose outer shape to the grid of the assembly fields of the respective busbar system is adjusted. The assembly fields can then be tight without gaps occupied with the required switching devices become. Each of them then usually immediately parallel next to each other arranged switching devices can over the busbar block belonging to the respective assembly field directly electrical energy to be supplied. For this purpose, coupling plug can be provided be.

One Problem occurs but when in addition to the switching devices also special devices, like e.g. Control transformers, unipolar consumers u.v.m., whose housing is not is adapted to the grid of the assembly fields or no electrical Connection to the assigned busbar block using a Enable coupling plug, to be placed on the busbar system. Also at one Such mixed equipment need such Special equipment over the Busbar without restriction from their full current carrying capacity with electrical energy can be supplied. For this purpose are so far consuming Wiring necessary, for. a control transformer with electrical energy to be able to provide in a coupled on a plurality of busbar blocks with associated Assembly panels distributed group of switching devices must be mounted. There the necessary cables must be laid freely, the clarity and operability of such a structure are significantly affected.

Of the Invention is based on the object, a busbar system so on, that in a simpler way a supply of special devices mounted on it with electrical energy without limiting the full current carrying capacity the busbars possible is.

The The object is achieved with the busbar system specified in claim 1 solved. Advantageous further embodiments are in the subclaims specified.

Especially advantageous embodiments and the advantages associated with it are described below using the example of explained in more detail busbar system shown in the figures.

there shows

1 an exemplary embodiment of a designed according to the invention connector with integrated outlet terminal in a side view,

2 the exemplary connector of 1 in a plan view,

3 a busbar system for switching devices according to the invention, that by way of example comprises two modules which can be coupled by means of a connector plug with integrated output terminal,

4 a plan view of the busbar system of 3 wherein, by way of example, a connection plug with integrated exit clamp is inserted at the outer end of the second module,

5 the busbar system of 4 , wherein a first connector with integrated output terminal for connecting the two modules and another connector with integrated exit terminal is inserted at the outer end of the second module, and

6 the busbar system of 5 , with additional narrow devices in the one Bauplätzen next to the exit terminals of the connector are used and are supplied via this with electrical energy from the busbar.

3 shows an example of a busbar system 3 for switching devices. This consists of a base module 31 and an expansion module 32 , which with the base module 31 mechanically and electrically coupled so that in particular the integrated, preferably three-phase busbars are electrically looped through. If required, the system can be supplemented with additional expansion modules, which can be found in the in 3 illustrated example on the right side of the expansion module 32 would be grown. The basic module 31 has a feed terminal as main components on the left side 311 with phase connections 3111 . 3112 . 3113 to supply the integrated busbar and a right adjoining mounting plate 312 on. In this is in the upper region a transverse first, preferably three-phase busbar 3121 integrated. This switchgear can be electrically powered on the mounting plate 312 are locked in place. Via a coupling plug 3122 at the right end of the mounting plate 312 may be the first busbar 3121 with a second, also preferably three-phase busbar 3221 be contacted, which in the upper part of the expansion module 32 is integrated. The expansion module has this feature 32 at its left end via a corresponding left coupling plug 3222 , If on the right side of the expansion module 32 another extension module should be connected, so its integrated busbar via a right coupling plug 3223 with the busbar 3221 in the extension module 32 be contacted.

The electrical connection of the two coupling plugs 3122 . 3222 and the coupler plug 3223 with an optional right adjoining coupling plug another, in 3 Expansion module, not shown, via connector 1 respectively. 2 , These are designed so that an unrestricted forwarding of the provided for the integrated busbars maximum current between the base module and the following expansion modules is possible.

In 3 Two types of coupling connectors are exemplified. The coupling plug 10 is advantageous according to the in the DE 101 56 214 described execution as a double Lyra connector. This allows a transfer of the full busbar load current, eg 32 A. The coupling plug 20 is designed according to the present invention, thus has an additional, integrated exit clamp 27 on. The structure of the plug base corresponds 23 largely the coupling plug 10 , ie is also advantageously designed as a double Lyra connector for maximum current carrying capacity. In addition is an exit clamp 27 preferably integrally integrated, ie advantageous to the plug base 23 placed. Using this, the supply voltage can be diverted from the busbars without restriction of the respective permissible maximum current, eg 32 A, for special devices. The structure of the coupling plug 10 . 20 is also the example of the 1 . 2 be explained. Advantageous uses of the coupling plug 20 are exemplified by the 4 - 6 will be explained in more detail.

The basic module 31 in 3 has a mounting surface 3123 with for example two bays 31a . 31b , which is right next to the power terminal 311 lie. The bays are in the example of 3 largely vertically oriented. This is at the head of the first slot 31a a device coupling 31a1 for connecting a switching device to the busbar 3121 , In the example of 1 is a circuit breaker 41 about mounting means 31a2 , which advantageously simulate the profile of a DIN rail, in the field of installation space 31a on the mounting surface 3123 fixed. The electrical connection with the busbar 3121 takes place with the help of a separate coupling plug 31a4 , This is on the head of the switching device 41 contacting so plugged that he into the assigned device coupling 31a1 intervenes. In the example of 1 is the mounting surface 3123 at the bottom of the slot 31a via an additional contactor socket 31a3 extended. This is a three-phase contactor 42 snapped, which the overlying circuit breaker 41 assigned.

The second slot next to it 31b on the mounting surface 3123 is in the example of 3 not used. Proves the same structure as the slot 31a on. At the head end is therefore a device coupling 31b1 for contacting with the integrated busbar 3121 available. About mounting means 31b2 In turn, a switching device can be snapped on.

The mounting plate 322 in the example of the 3 shown expansion module 32 has three bays 32a . 32b . 32c on their mounting surface 3224 on. Switching devices, which can be snapped on via the second integrated busbar, can then be snapped on via corresponding mounting means 3221 and at the head of each slot outgoing device couplings can be supplied with electrical energy. For a better overview, the expansion module 32 in the example of 3 not equipped with switching devices.

Depending on the individual case on the mounting surfaces 3123 and 3224 on zurastenden switching devices, the connection of the first and second busbar 3121 . 3221 via the coupling plug 3122 . 3222 either with the connector 1 in the from the DE 101 56 214 known type or with the connector 2 respectively. If necessary, an extended according to the invention by an integrated branch terminal connector 20 also in the right coupling plug 3223 be plugged. This can be devices that have special designs and thus not with a coupling plug 31a4 can be connected to a busbar of the busbar system, are supplied by means of a shortest and outgoing from the branch terminal cable wiring with energy. Examples are given by means of 4 to 6 will be explained in more detail.

As in 3 shown, the connector has 10 preferably a top 10 with a front and support plate 11 on, for example, a handle 12 to facilitate the pulling and plugging of the connector is located. The plug pedestal 13 is preferably designed in three phases and has three double contacts 14 . 15 . 16 on. That's the first double contact 14 via a first contact opening 141 in the left coupling plug 3122 and a second contact opening 142 in the right coupling plug 3222 one. The double contact is preferably designed as a lyra or double Lyra contact with at least four lyra contacts per phase.

Like from the 1 . 2 . 3 can be seen, is the plug base 23 of the connector 2 constructed accordingly. A first, second and third double contact 24 . 25 . 26 are over a front and support plate 21 covered. When using the connector 2 for connecting the busbars 3121 and 3221 For example, picks up the first contact opening 241 of the first double contact 24 in the left coupling plug 3122 and the second contact opening 242 in the right coupling plug 3222 one. According to the invention is additionally an integrated, preferably patch outlet terminal 27 available. Preferably, this is asymmetrical on the top 20 put on that one remaining part 22 not from the output terminal 27 is covered. It is particularly advantageous when the exit clamp 27 so asymmetrical on the top 20 of the connector 2 is attached, that this depends on the insertion of the connector 2 in the area of a module to the right or left of it 3221 . 3121 extends, and the remaining top 22 of the connector 2 not on the left or right module 3121 . 3221 survives. This embodiment and the resulting possibilities are described below using the examples of 4 to 6 will be explained in more detail.

On the top 271 of the connector 2 In the case of a three-phase design, there are three pairs of a contact outlet and an associated tool intervention. So can in the first contact departure 274a a connection cable to be contacted, if necessary by engaging a corresponding tool in the tool engagement 274b can be solved again. In the same way, the two other contact outlets and associated tool engagements are designed. Such a connector with attached output terminal has the FITS advantage that not only the busbars of adjacent modules can be contacted with each other, but that at the same time a cable-powered power supply of devices in special cases is possible without sacrificing the current carrying capacity. Such power values can be achieved particularly easily if the double contacts in the connector base 23 again in the form of double lyra compounds are executed.

The top views of 4 - 6 show the example of in 3 already explained construction of a busbar system that, for example, a base module 31 and an expansion module 32 has, various ways of using a connector with integrated output terminal. So in the example of the 4 all bays 31a . 31b on the mounting plate 312 of the base module 31 and all bays 32a . 32b . 32c on the mounting plate 322 of the expansion module 32 with circuit breakers 41 . 43 . 45 . 47 . 49 stocked. These are via the device couplings 31a1 . 31a2 .. of the respective slot and an associated coupling plug supplied directly from the underlying busbar with electrical energy. The busbars of the modules 31 . 32 are via a connector 1 electrically contacted. This is not above the mounting surfaces of the two adjacent mounting plates 312 . 322 In addition, so that the five bays can be fully occupied eg with circuit breakers. These are then, as in the example of 4 to see, close to each other.

In addition, the right-hand coupling plug is 3223 at the far right end of the expansion module 32 with a connector 2 occupied, the one asymmetrically attached exit clamp 27 having. In this case, the connector has 2 in the coupling plug 3223 such a plug-in direction that the exit clamp is directed to the right and not in the left-side slot 32c extends. This is therefore unrestricted with a standard switching device 49 verifiable. With the help of the protruding exit clamp 27 it is now possible to integrate the voltage busbars via connected cables to other, in 4 To guide devices not shown and to feed them electrically.

At the in 5 Example shown is in place of the connector 1 a connector 2a with attached outfeed terminal for connecting the busbars of base module 31 and expansion module 32 used. The slot 32a is due to the above exit terminal now no longer equipped with a switching device. However, this can be done in the same way as from the exit terminal of the rightmost end of the other connector 2 the busbar voltage is tapped and supplied to other, not shown electrical loads.

In 6 is again the busbar system of 5 with the connectors 2a and 2 B shown, each having an attached outlet terminal. However, the connectors are so turned used that the slot 31b from the exit clamp of the connector 2a and the slot 32c from the exit clamp of the connector 2 B partially occupied. The remaining bays are in the same way as in 4 with switching devices 41 . 45 . 47 stocked. According to a further advantageous embodiment of the invention, the housing of the exit terminals extend only in part of the bays 31b and 32c , It is particularly advantageous if they occupy only about half of a slot. In the remaining halves of the bays then next to the exit terminals of the connector 2a . 2 B additional narrow devices 51 . 53 , For example, single-pole circuit breaker, used and are supplied via the exit terminals by means of cable connections with electrical energy from the underlying busbar.

Claims (9)

Busbar system for the electrical supply of several switching devices ( 41 . 42 ), with a base module ( 31 ), which is a first, integrated busbar ( 3121 ) for at least one switching device, which via a power terminal ( 311 ) for the electrical supply of the first busbar ( 3121 ) and with at least one expansion module ( 32 ), which has a second, integrated busbar ( 3221 ) for at least one further switching device, and with a connector ( 1 ) between the first and second busbars ( 3121 . 3221 ) in order to make their electrical contact, characterized in that in a connector ( 2 . 2a . 2 B ) an additional exit clamp ( 27 ) is integrated. Busbar system according to claim 1, wherein the additional outfeed terminal ( 27 ) in one piece with the connector ( 2 . 2a . 2 B ) connected is. Busbar system according to claim 1 or 2, wherein the additional outfeed terminal ( 27 ) on the top ( 20 ) of the connector ( 2 . 2a . 2 B ) is attached. Busbar system according to claim 3, wherein the additional exit terminal ( 27 ) so asymmetrically on the top ( 20 ) of the connector ( 2 ) is set up, that this depends on the insertion direction of the connector ( 2 ) in the area of the right or left of the module ( 3221 . 3121 ), and the remaining top ( 22 ) of the connector ( 2 ) does not have the left or right module ( 3121 . 3221 ) survives. Busbar system according to claim 4, wherein the additional outfeed terminal ( 27 ) depending on the insertion direction of the connector ( 2 ) only in a part of a slot ( 32a . 31b ) on an adjacent module ( 3221 . 3121 ). Busbar system according to claim 5, wherein the additional outfeed terminal ( 27 ) only in one half of a slot ( 32a . 31b ) on an adjacent module ( 3221 . 3121 ). Busbar system according to one of the preceding claims, wherein the supply terminal ( 311 ), Busbars ( 3121 . 3221 ) and connectors ( 1 . 2 ) are executed multi-phase. Busbar system according to one of the preceding claims, wherein at the free end of an expansion module ( 32 ) another connector ( 2 B ) with integrated exit clamp ( 27 ) for the busbar ( 3221 ) attachable ( 3223 ). Busbar system according to one of the preceding claims, characterized in that the connecting plug ( 1 . 2 ) is designed as a double lyra connector with at least four lyre contacts per phase, of which two are the first busbar ( 3121 ) in the base module ( 31 ) and the other two the opposite busbar ( 3221 )