DE4406688A1 - Method for combining components of different current rail systems - Google Patents

Abstract

The method involves combining electric components which belong to a group of different, non-compatible current rail systems with different current rail profiles, into a common current rail unit. Each group has a current rail and an appropriate adaptor. For the current rail of the combined system, a track profile (10) is selected in which the adaptor can be used for all of the current rail systems belonging to the group. The current rail used in the method has a flat receiving surface (22) for housing parts of the adaptor. A rectangular cross-section slit (20) for the engaging area of the adaptor opens out into the receiving surface (22). Four grooves (24) are formed in opposing pairs in the sides of the slit (20) and each receive an electric lead (26). Two opposing anchoring grooves (30) are provided in the section of the slit (20) between the leads (26) and the receiving surface (22). Another groove (32) is formed on one side of the slit (20).

Description

The invention relates to a method for combining electrical components, the to several, each one busbar and associated Power rail systems comprising adapters that are not compatible with each other belong in a common power rail system as well as a power rail to carry out this procedure.

Busbar systems are used to supply electrical power to the mains Consumers such as lights and the like and include essentials Elements of a track with a slot in which the electrical conductors are arranged, and associated adapters, which are mechanical are lockable in the receiving slot and the tap of the mains voltage from the conductors of the conductor rail. The currently marketable Busbar systems are mutually basic in their structure similar.

The receiving slot is substantially rectangular in cross section, and the Opening into which the adapter can be inserted corresponds to a narrow side of this Rectangle. In the opposite side walls of the slot four grooves are formed, which are opposite each other in pairs and each take up an electrical conductor. Closer to the opening are formed two further mutually opposite grooves in which mechanical anchoring parts of the adapter can engage. A fifth electrical conductor, which serves as a protective conductor, lies directly in a flat groove at the neck of the slot.

The adapter has an engagement part that can be inserted into the receiving slot on which the electrical contacts and mechanical anchoring parts are arranged retractable. If the engaging part in the busbar is inserted, the contacts and the anchoring parts are spread and so engaged with the corresponding grooves.

In the existing track systems, the profiles of the Busbars a bit in terms of the position, width and depth of the grooves from each other, and the adapters are each specific to the associated one Adjusted busbar so that the adapter only the one to the same  System-belonging track can be used. If the user he has decided on a certain track system therefore basically committed to this system and it is not straightforward possible to retrofit the track with lights or others To equip consumers whose adapters belong to a different system.

In order to overcome this lack of flexibility, it is known, so-called Universal adapter to use, where the contacts and the anchoring parts are designed so that they fit into all common busbars.

However, making such a universal adapter is difficult because of it the adapters are complicated electromechanical functional parts which is given by the different busbars It is difficult to adhere to framework conditions. In addition, the Disadvantage that the dimensions of each contact in the universal adapter and align each anchoring part with the track system must, in which the intended to take up this contact or anchoring part Groove is smallest. For this reason, increased quality requirements can be met with regard to functional reliability and mechanical strength the anchorage does not always meet.

From the perspective of the end user, this solution also has the Disadvantage that he with the subsequent assembly of his track with other lights is still limited to those lights with are provided with a universal adapter. Therefore, he still does not have that Possibility to integrate a light into his track system, which provided with an original adapter from another busbar system is.

The invention has for its object a method for combining electrical components from different busbar systems to indicate that a high level of functional reliability and stable anchoring The adapter in the power rail ensures even when the adapter do not belong to the same system as the busbar.

This object is achieved with those specified in claim 1  Features resolved.

According to the basic idea of the invention, the compatibility of the different Systems not achieved by a universal adapter as before, that fits for all possible tracks, but on the contrary, a universal busbar is created, in which everyone eligible adapters can be used.

This has the advantage that the relatively complicated trained No design changes need to be made to adapters, that could impair the functional safety. It just takes the hollow profile of the busbar, which is easily extruded can be made to be chosen so that the position and size differences of the contacts and anchoring parts of the different Adapter through appropriate dimensioning of the receiving slot and the grooves are balanced.

Another advantage is that the user after installation the power rail does not depend on the use of adapters of a particular System or by universal adapters, but in combination with the busbar also lights or other electrical Consumers who use an original adapter of any kind common busbar system are provided.

A conductor rail suitable for carrying out this method is the subject of claim 3. The shape of the track profile specified in this claim enables the use of adapters from a variety of commercially available busbar systems.

Advantageous further developments and refinements of the busbar are shown in specified in the subclaims.

The busbar is preferred by an integral plastic extruded profile formed, which has no stiffening parts made of metal. The necessary Torsional stiffness is achieved in that the receiving slot between forming inner wall and an outer wall of the busbars a plurality of profile chambers is formed by stiffening webs  are separated from each other.

The following is a preferred embodiment of the invention Busbar explained in more detail using the drawing.

It shows:

Fig. 1 shows the profile of the busbar and

Fig. 2 shows the conductor rail profile from Fig. 1 with dimension lines.

The busbar is formed by a one-piece profile strand 10 made of plastic, which has a substantially circular segment-shaped outer wall 12 and an inner wall 14 which is connected to the outer wall by a plurality of approximately radially extending webs 16 , so that in the space between the inner wall and the outer wall a torsion and bending resistant honeycomb structure with a plurality of profile chambers 18 is formed. The profile chambers 18 can be used for receiving electrical lines and the like.

The inner wall 14 delimits a receiving slot 20 into which various adapters (not shown) with their respective engagement area can be inserted. On both sides of the mouth of the receiving slot 20 , the extruded profile 10 has a flat contact surface 22 for the parts of the adapter remaining outside the receiving slot.

In the side surfaces of the receiving slot 20 , four mutually opposite grooves 24 are formed at two different depths, at the bottom of which an electrical conductor 26 is locked. Between the grooves 24 lying on the same side, two separate elastic webs 28 are arranged in each case, which limit the grooves and enable the conductors 26 to snap into place. Between the mouth of the receiving slot 20 and the grooves 24 , two opposing deeper locking grooves 30 are formed, which serve to receive expandable anchoring parts of the adapter and thus to mechanically anchor the adapter in the busbar. Between the locking grooves 30 and the mouth of the receiving slot 20 , an additional locking groove 32 is formed on one side, left in the drawing. On the opposite side, a protective conductor 34 is locked in the extruded profile 10 at the corresponding point.

The shape and the dimensions of the extruded profile 10 are chosen so that as many different commercially available adapters fit into the conductor rail.

The meaning of the dimensions given below follows from FIG. 2.

The receiving slot 20 has a constant minimum width W1 of 15.2 mm down to a depth H1 of 25.8 mm. In a central area with a width W2 of 8.8 mm, the receiving slot has a total depth H10 of 29.9 mm. At the bottom of the receiving slot 20 , a groove 36 with a rectangular cross section is thus formed, which passes over inclined surfaces 38 with an inclination angle of 30 ° into the wider main section. This allows adapters in which the engagement area has a large overall height, as well as adapters with a relatively wide engagement area. In the cases in which the engagement area has an average width and height, the inclined surfaces 38 serve to support the engagement area, so that in these cases too, stable support of the adapter in the receiving slot 20 is ensured.

The distance W3 between the contact surfaces of the conductors 26 and the center plane of the busbar is approximately 10.5 mm. However, the conductors 26 in the example shown have a cup-shaped profile, so that the distance W varies somewhat depending on the depth. The profile of the conductor 26 is chosen so that an approximately uniform contact pressure is ensured with all adapters used. The center positions of the grooves 24 are adapted to the adapters in which the contacts protrude the most. In adapters, the contacts of which project less far outwards, the contact spacing is also somewhat different, so that the contacts here lie in the less deep regions of the grooves 24 .

The width of the grooves 24 is chosen so that different contact distances between the different adapter types can be compensated. The boundary surfaces of the grooves 24 have the distances H3 = 21.8 mm, H4 = 19.8 mm, H5 = 15.2 mm and H6 = 12.2 mm from the contact surface 22 .

The locking grooves 30 have a depth W4 = 14.8 mm (measured from the central plane), and the distances between the boundary surfaces and the contact surface 22 are H7 = 8.4 mm and H8 = 5.5 mm. In addition, the anchoring grooves 30 on the opposite side of the contact surface 22 have two approximately 40 mm deep indentations 40 which are adapted to the plug-in profiles of different types of feeders and busbar connectors.

The additional anchoring groove 32 has a depth W5 = 13.8 mm, and its boundary surfaces lie at distances H9 = 3.9 mm and H10 = 1.8 mm from the contact surface 22 . The additional anchoring groove 32 enables the use of some special adapter types, in which an anchoring part is provided at this point.

Some types of adapters also have a protrusion on one side on the surface that bears against the contact surface 22 , which ensures that the adapter can only be inserted into the busbar in the orientation in which a protective conductor contact of the adapter bears against the protective conductor 34 . For these adapter types, a groove 42 is provided for the extruded profile 10 in the contact surface 22 next to the mouth of the receiving slot 20 , the edges of which have the distances W6 = 12.2 mm and W7 = 16.0 mm from the central plane. The projections of the relevant adapter types can be received in this groove. If the width of the adapter in the area of the contact surface 22 is greater than the dimension W7, the conductor rail is completely closed off by the adapter on the underside, so that no disruptive groove remains visible between the conductor rail profile and the adapter.

While conventional busbars mostly made of an aluminum profile exist, in which an insulation profile made of plastic is used only in the vicinity of the electrical conductor, there is an essential feature of the embodiment shown in that the entire profile of the busbar is made of plastic. This not only enables simple and rational production, but also has the advantage that the inherent elasticity of the plastic contributes to the dimensional deviations between to compensate for the different adapter types.

In another embodiment, however, it is possible to produce the outer wall 12 of the busbar, including the regions which form the contact surface 22 , from metal, while the inner wall 14 of the busbar, including the webs, which delimit the anchoring grooves 30 , are formed by an integral plastic profile .

The outer wall 12 of the extruded profile 10 forms two diametrically opposite grooves 44 in the example shown. These grooves also allow the use of adapters which grip around the conductor rail profile in the form of pliers. In this case, the free ends of the tong arms can engage in the grooves 44 .

On the upper side, the outer wall 12 of the extruded profile 10 forms a flattened area 46 for the direct ceiling mounting of the busbars and two symmetrically arranged hooks 48 , between which an extruded profile of a ceiling suspension or the like can be locked.

Claims (8)

1.Method for combining electrical components belonging to a certain group of busbar systems, each comprising a busbar and associated adapters, which are incompatible with one another and having similar busbar profiles, in a common busbar system, characterized in that for the busbar of the busbar system a continuous profile ( 10 ) is selected in which the adapters of all busbar systems belonging to the group can be inserted. 2. The method according to claim 1, characterized in that the contact surfaces of the electrical conductors ( 26 ) of the busbar are profiled such that different projecting lengths of the contacts in different adapters are compensated for by position differences of the contacts in the direction of the depth of the receiving slot ( 20 ) of the busbar . 3. conductor rail for performing the method according to claim 1 or 2, with

• - a flat contact surface ( 22 ) for housing parts of the adapter,
• - a receiving slot ( 20 ) opening into the contact surface ( 22 ) with a substantially rectangular cross section for engagement areas of the adapters,
• four grooves ( 24 ), which are formed in pairs opposite one another in the side surfaces of the receiving slot ( 20 ) and each receive an electrical conductor ( 26 ),
• - two mutually opposite anchoring grooves ( 30 ) in the section of the receiving slot ( 20 ) between the conductors ( 26 ) and the contact surface ( 22 ),
• - An additional anchoring groove ( 32 ) which is formed on one side of the receiving slot ( 20 ) between the main anchoring groove ( 30 ) there and the contact surface ( 22 ), and
• a protective conductor ( 34 ) arranged opposite the additional anchoring groove ( 32 ),
  characterized by the following features:
• Receiving slot ( 20 ) has a width of at least 15.0 mm up to a depth H1 of at least 25.5 mm and a depth of at least 27.5 mm in the middle region over a width of at least 9.0 mm,
• - The grooves ( 24 ) used to receive the conductors ( 26 ) have a depth W3 of approximately 11 mm measured from the center plane of the busbar to the contact surface of the conductor,
• in the case of the two grooves ( 24 ) located deeper in the receiving slot, the distance H3 between the inner boundary surface and the contact surface ( 22 ) is at least 21.0 mm and the distance H4 between the outer boundary surface and the contact surface is at most 19.0 mm,
• - In the case of the two grooves ( 24 ) located less deeply in the receiving slot, the distance H5 between the inner boundary surface and the receiving surface ( 22 ) is at least 14.8 mm and the distance H6 between the outer boundary surface and the contact surface is at most 12.5 mm,
• - The depth W4 of the anchoring grooves ( 30 ) measured from the central plane of the busbar is at least 12.5 mm, the distance H7 from the inner boundary surface of these anchoring grooves to the contact surface ( 22 ) is at least 8.2 mm and the distance H8 from the outer boundary surface to the contact surface ( 22 ) is at most 5.5 mm,
• - The depth W5 of the additional anchoring groove ( 32 ) is at least 13.5 mm, the distance H9 of the inner boundary surface of the additional anchoring groove ( 32 ) to the contact surface ( 22 ) is at least 3.9 mm and the distance H10 of the outer boundary surface to the Contact surface at most 1.8 mm.

4. Busbar according to claim 3, characterized in that in the contact surface ( 22 ) on the side of the receiving slot ( 20 ) on which the protective conductor ( 34 ) is located, a further groove ( 42 ) is formed. 5. Busbar according to claim 3 or 4, characterized in that the wider section of the receiving slot ( 20 ) in the narrower and deeper section ( 36 ) over inclined surfaces ( 38 ) which is at an angle of about 30 ° to the contact surface ( 22nd ) run. 6. Busbar according to one of claims 3 to 5, characterized in that the busbar is formed by a one-piece extruded profile ( 10 ) made of plastic, which has a receiving slot ( 20 ) delimiting inner wall ( 14 ), an outer wall ( 12 ) and several Has inner wall and the outer wall connecting webs ( 16 ) and in which the protective conductor ( 34 ) is locked. 7. Conductor rail according to one of claims 3 to 5, characterized in that at least the limitation of the receiving slot ( 20 ) including the grooves ( 24 ) for the conductors ( 26 ) and the main anchoring grooves ( 30 ) are formed by an integral plastic extruded profile becomes. 8. Busbar according to one of the preceding claims, characterized in that the conductors ( 26 ) are concavely profiled on their surface in the groove ( 24 ).