DE10146720A1 - Electrical ribbon cable has at least one insulation stripping point allowing cable electrical conductors to be revealed - Google Patents

Abstract

The ribbon cable (2) has at least one electrical conductor (4) and at least one insulation layer (6) at least partially covering the electrical conductors and provided with at least one insulation stripping point (8) allowing the electrical conductors to be revealed. The electrical conductors can be provided by Cu bands, the insulation layer adhered to at least one conductor and removed at the insulation stripping point via laser light. Also included are Independent claims for the following: (a) a manufacturing method for an electrical ribbon cable: (b) a device for manufacture of an electrical ribbon cable

Description

The present invention relates to a ribbon cable according to the preamble of claim 1.

It also relates to a device for producing the ribbon cable according to the preamble of claim 9.

It also relates to a method for producing the ribbon cable according to the preamble of claim 6.

Ribbon cables offer an elegant way to use a variety of conductors weight-saving and clearly laid together. It is necessary to attach a large number of conductors to the ends of the ribbon cable to contact. It is also necessary to branch or in the course of the cable To create contact points.

For this purpose, recesses are made in an insulation layer at the stripping points of the cable created to expose the conductor. This stripping is however, often difficult due to the close proximity of other conductors.

State of the art

The following methods are known for stripping the ribbon cable locally:
With thermal stripping, the insulation layer is heated locally above its melting point. Then the softened insulation material is mechanically, e.g. B. removed by pliers.

However, this method can be used for very thin conductors or for hard ones Additional conductors (e.g. glass fibers) can damage the conductors.

The insulation layer can also be locally evaporated by means of laser radiation become. The problem here is that the exposed surfaces of the Conductors are often not suitable for proper solder contact.

The insulation layer can also be removed by milling. However, there is the following difficulty:
In the manufacture of ribbon cables, electrical conductors are embedded between two insulation layers using an adhesive. Here, a conductor within the adhesive layer comes undefined closer to one or the other insulation layer. In addition, the conductor is not completely flat on its surface.

Now a certain layer thickness of the insulation layer becomes with the milling cutter removed, it is not possible to predict whether the conductor will be exposed at all is whether it is still partially covered due to its wavy surface, or whether it has already been damaged during milling. Correct contactability and In any case, defined electrical resistance is questionable. The procedure is cannot be automated.

By grinding with grindstones it is through certain grinding materials possible to remove the insulation layer without attacking the conductor. This However, the process is only for a limited number of geometric arrangements used. In addition, the materials on the market are only limited available.

According to the state of the art, this is not a process or a ribbon cable available, which is an efficient and flexible manufacturability with good Connectability and defined conductor resistance connects.  

Subject of the invention

The subject of claim 1 has at the stripping point by Irradiation with granular material leaves a bare, clean contact surface that is free of residues of the insulation layer.

A large number of solids with one is here under granular material Understand diameter less than 5 mm, in particular less than 1 mm. in this connection grains of sand or the like come into question. However, glass Pearls.

Irradiation with solids is understood to mean that the solids as Beam of material can be thrown onto the irradiated object. Come to this for example, centrifuges.

Claim 6 defines the manufacturing method and Claim 9 the corresponding manufacturing facility. More beneficial Explanations can be found in the subclaims.

characters

The following description deals with options for designing the Invention. These statements are only to be understood as examples and are made with reference to:

Fig. 1 shows a first embodiment of a ribbon cable according to the invention in plan view

Fig. 2 shows a second embodiment of a ribbon cable in plan view

Fig. 3 is a schematic view of a manufacturing device for the ribbon cable according to the invention.

Description of the invention

Fig. 1 shows a ribbon cable 2 with conductors 4 , 4 '. These run essentially parallel to each other. They are formed by flat metal strips, in particular made of copper.

The conductors 4 , 4 'are arranged on an insulation layer (not shown because it is covered) and covered with a second insulation layer 6 .

The two conductors 4 are exposed at a stripping point 8 like a window. The contact surfaces 10 exposed here are blasted with granular material.

Fig. 2 shows a second embodiment. This ribbon cable 2 also has conductors 4 which are covered with an insulation layer 6 .

Here, the stripping points 8 are provided at one end of the cable. Here, all of the conductors 4 are exposed at their ends. They have also been irradiated with granular material at the contact surfaces 10 thus created.

Fig. 3 shows schematically the path S of a flat cable by a manufacturing device 12. The production device has a laser 14 , a glass bead beam device 16 and a device for transporting the ribbon cable along the path S.

The ribbon cable ( 2 ; in Fig. 3 with a portion of the path S congruent) is arranged unprocessed from a position A in front of the laser 14 to a position B under the laser 14 .

In this position B, the laser 14 is used to direct a laser beam 18 onto the ribbon cable 2 . This laser beam 12 evaporates the insulation layer 6 at the stripping point 8 . However, a fine residual layer of the insulation material remains on the contact points 10 .

The ribbon cable is then removed under the laser 14 and brought into a position C. From there it is positioned in a position D under the glass bead blasting device 16 . Here a beam of glass beads is thrown onto the stripping point 8 . When they hit the stripping point 8, the glass beads cause the thin remaining layer of insulation material to chip off on the contact points 10 .

Through a suitable choice of treatment duration and glass bead speed can be achieved that the residual layer is removed without significantly attacking the more stable conductor material.

Incidentally, in the areas in which no laser radiation has previously acted, there is no weakening of the material of the insulation layer 6 during glass bead blasting. The thickness of the remaining insulation layer 6 in connection with the elasticity of the material offers a sufficient spring travel and allows the glass beads to rebound ineffectively.

The surface of the conductor 4 at the contact point 10 resulting from this method is free of insulation material despite any ripples. In addition, it is slightly roughened by the pearl radiation and is well suited for soldering.

Claims (11)

1. ribbon cable ( 2 ) with at least one electrical conductor ( 4 , 4 ') and at least one insulation layer ( 6 ) which at least partially covers the conductor ( 4 , 4 ') and which at least one stripping point ( 8 ) the conductor ( 4 , 4 ') is uncovered, characterized in that the conductor ( 4 ) has a surface irradiated with granular material at least in the region of the stripping point ( 8 ). 2. Ribbon cable according to claim 1, characterized in that the insulation layer ( 6 ) with the at least one conductor ( 4 ) is glued. 3. Ribbon cable according to one of the preceding claims, characterized in that at least three substantially parallel conductors ( 4 , 4 ') are provided. 4. Ribbon cable according to one of the preceding claims, characterized in that the conductor ( 4 , 4 ') is made of flat copper. 5. Ribbon cable according to one of the preceding claims, characterized in that the insulation layer ( 6 ) at the stripping point ( 8 ) is removed with laser light. 6. A method for producing a ribbon cable ( 2 ) according to one of the preceding claims, according to which at least one conductor ( 4 ) of the ribbon cable ( 2 ) has its insulation layer ( 6 ) removed by means of light radiation at least at one stripping point ( 8 ) (at least partially), thereby characterized in that at least the stripping point ( 8 ) is irradiated with granular material. 7. The method according to claim 6, characterized in that the granular material ( 20 ) are glass beads, in particular with a diameter of less than 1 mm. 8. The method according to claim 6 or 7, characterized in that the light radiation ( 18 ) is laser radiation. 9. Device for producing a ribbon cable ( 2 ) according to one of claims 1 to 5, with a device ( 14 ) for irradiating the ribbon cable ( 2 ) with light ( 18 ), characterized in that it has a device ( 16 ) for irradiating the Has ribbon cable ( 2 ) with granular material ( 20 ). 10. The device according to claim 9, characterized in that the granular material ( 20 ) are glass beads, in particular with a diameter of less than 1 mm. 11. The device according to claim 9 or 10, characterized in that the light ( 18 ) is laser light.