EP4327413A1 - Input/output devices with injection-molded lines - Google Patents

Abstract

The invention relates to a method for producing an assembly (1) and to an assembly (1) for distributing data, comprising an input/output device (2) with at least two interfaces (11, 13) for transmitting data between participants (8, 9) connected to the interfaces (11, 13), wherein data cables (3, 4) are provided, via which the respective participant (8, 9) is connected to the interface (11, 13) corresponding to said participant at the completed input/output device (2). The invention is characterized in that a housing of the input/output device (2) is produced in a plastic injection molding method, and in the process a respective end region of the data cable (3, 4) is surrounded by the housing.

Description

INPUT-OUTPUT DEVICES WITH MOLDED CABLES

description

The invention relates to an arrangement for distributing data and a method for producing such an arrangement for distributing data according to the features of the respective preamble of the independent patent claims.

An arrangement for distributing data, but no manufacturing method for such an arrangement, is known from utility model DE 93 05 529 U1. An input-output device has a housing on which plug-in connections are provided as interfaces, via which plug-in connectors can be optionally plugged in (and also unplugged again). Data cables are connected to these connectors, at the other end of which a participant, such as a sensor, an actuator or the like, is connected. One of the participants is designed to connect the device to a higher-level control unit, with data being sent (distributed) via the input-output device to the participants (such as the sensors or actuators mentioned) or received by them.

In this prior art, the connectors that are connected to the interfaces of the input/output device are in the form of plug-in screw connections. Although such a design has proven itself in practice, especially with regard to the reliability of this connection and its tightness, it is disadvantageously necessary to manufacture a large number of parts (such as devices, data cables, connectors, subscribers) separately from each other and can also be mounted separately later in the field. Due to the large number of elements of the arrangement that have to be assembled in the field, it cannot always be guaranteed that the assembly has been carried out correctly, so that it can happen, for example, that the assembly of the plug-screw connection has not been carried out properly as a result of a slanted connection and it can therefore lead to transmission difficulties, but also to leaking problems.

The object of the invention is therefore to improve a generic arrangement and to avoid the disadvantages described at the outset.

In addition, a method for producing such an arrangement is to be specified with the invention.

These objects are solved by the features of the independent patent claims.

With regard to the arrangement for distributing data, according to a first variant, the invention provides that a housing of the input/output device is a housing produced in a plastic injection molding process and a respective end area of the data cable is surrounded by the housing. This means that with the production of the housing of the input/output device in a plastic injection molding process, which protects the interior, in particular the sensitive electrical and electronic components of the input/output device in field use, it also surrounds the end area of at least one data cable, so that a medium-tight connection that is resistant to mechanical stress is implemented there. On the one hand, this eliminates the expensively designed plug-in screw connections and their disadvantages with regard to incorrect assembly and leaks. The length of the overmolded area of the data cable, in particular its outer sheath, is chosen so that on the one hand Longitudinal watertightness is achieved, but on the other hand mechanical loads, such as tensile and compressive stresses, as well as buckling movements, are resisted.

In a second variant, the invention provides that a housing of the input/output device is made of a metal material and that an interior area of the housing is cast with a plastic material, with the plastic material extending over at least the respective end area of the data cable. The use of a metal material for the housing has the advantage that this shields the interior, so that further shielding measures can be omitted. For this purpose, the shielding of the respective data cable is electrically contacted directly or indirectly (for example via connecting means such as cables, springs or the like) with the metal housing.

A metal housing (e.g. made of die casting) could also be considered, which is overmoulded with plastic, with this overmoulding the ends of the lines that lead into the housing being overmoulded at the same time, or the overmoulding even up to the connected sensors/actuators enough. This means that the second shell (housing) is applied around the metal housing by means of an injection molding process to improve haptics, for design reasons, but also for functional reasons. In particular, IP protection is achieved by the outer housing made of plastic. With very short lengths of the connected data cable, only strands could be used instead of the complete line, which is then routed to the sensors via a kind of anti-kink sleeve. Otherwise, the advantages listed above for the first variant also remain in this second variant. Casting out the inner area of the metal housing (similar to the further variant described below) is also conceivable here. In a further variant, the invention provides that a housing of the input/output device is made of plastic and that an interior area of the housing is cast with a plastic material, with the plastic material extending over at least the respective end area of the data cable. A liquid medium is introduced into the interior (cavity) and hardens there. The cavity can be filled completely or only partially. The potting (or also referred to as pouring out) of the interior has the advantage that it is effectively protected from external influences such as dust, moisture, liquid and the like. Otherwise, the advantages listed above for the first and/or second variant also remain in this further variant.

It is also conceivable to produce a housing from plastic (for example in the plastic injection molding process or another process) and then to overmold this plastic housing, including the lines that lead into the plastic housing, with plastic again. Using a 2-component injection molding process, a housing can be made, for example, from a suitable, harder plastic, with the sealing at the housing interfaces for the cables being implemented at the same time using a softer plastic.

In principle, the same plastic material should be used for the housing as for the outer sheath of the cables. Alternatively, it can also be different plastic materials that are processed in a 2-component injection molding process. For a good seal, it is always an advantage if the plastic has the same material properties as the cable sheath. But there are also other criteria such as media resistance, flammability, smoke development or transparency that require a different plastic than the cable. Above all, cables must be abrasion-resistant and flexible, so that different materials, which are introduced via a 2-component injection molding process, make perfect sense. In a development of the invention, it is provided that a housing of at least one of the participants is molded onto an end area of its associated data cable. While in the prior art the participants, such as the sensors, actuators or the like already mentioned, are also connected via plug-in connections, such as the plug-in screw connections already mentioned, and this results in the same disadvantages described, the advantage is also exploited here that a housing of the subscriber is produced in a plastic injection molding process and an end area of the respective data cable is also overmoulded. This also ensures longitudinal watertightness, the number of elements to be assembled is reduced in field operation and consequently incorrect assembly, such as slanted assembly and thus transmission errors and leaky plug-screw connections, are ruled out.

So far it has been assumed that at least one of several data cables with its associated end area is molded onto the housing of the input/output device and optionally at least one end area of a data cable onto a housing of at least one participant. This means that it is not impossible to provide additional interfaces in the input/output device, into which plug connectors can be plugged in, as is the case, for example, in the prior art described at the outset.

In order to optimize the tightness of the entire arrangement and to reduce the number of elements to be assembled in field operation, the invention provides that all data cables are surrounded by the housing of the input/output device and the housings of all participants are molded onto the end area of their associated data cable . This creates a self-contained arrangement that is sealed against external influences. It is also possible, after prior measurement of the location of the arrangement to produce an individually designed arrangement for distributing data with regard to the placement of the input-output device and also with regard to the length of the data cables between the input-output device and the arrangement of the respective participants.

The variants of the arrangements for distributing data described above can be produced using the method according to the invention for producing such an arrangement.

Plastic injection molding methods are known in principle, in which the elements involved are placed in a plastic injection mold and then surrounded with a plastic.

According to the manufacturing method according to the invention, this means that the elements located inside the input-output device (such as a printed circuit board with electrical and electronic components arranged on it) and the end of a data cable to be surrounded with plastic of the housing are inserted into the injection mold and this Areas are then surrounded with plastic. As an alternative to this, it is conceivable that the housing of the input/output device is first produced without its interior elements, with the ends of the respective data cable, preferably the ends of all data cables, also being molded on. Once this is done, the electronics can be inserted into the interior of the two-part or multi-part housing and electrically connected to the data cables. The same also applies in the event that not only the ends of one or all of the data cables are overmoulded by the housing of the input/output device, but also at least one housing of a participant via the end of the data cable to which the participant is connected , is injected reaching over this end area of the data cable. An exemplary embodiment of an arrangement according to the invention, comprising an input/output device, is described below and explained with reference to the single figure.

An arrangement 1, as far as shown in detail, comprises an input/output device 2. This device 2 has a housing to which at least two data cables 3, 4 are connected. Device 2 is connected via data cable 3 to a higher-level control unit (not shown) and via data cable 4 to a participant, so that data is exchanged between the higher-level control unit via device 2 with the at least one participant. Such input/output devices 2 are known in principle and are also referred to as distributor modules, IO hubs or IO devices (I: input, O: output). In addition, reference is made, for example, to the utility model DE 93 05 529 U1 mentioned at the outset for the basic design and mode of operation of such devices.

In the exemplary embodiment in the single figure, further data cables 5 to 7 are led out of the housing of the device 2 in addition to the data cables 3 , 4 . A first subscriber 8 is connected to the data cable 3 , a subscriber 9 being connected to the data cable 4 . Of course, other participants are connected to the other data cables 5 to 7, but they are not shown for the sake of simplicity.

In principle, a respective participant can be a connector, a sensor, an actuator or the like. In the exemplary embodiment according to the figure, subscriber 8 is designed as a plug connector, via which arrangement 1 can be detachably connected to the superordinate control unit (not shown). According to the invention, the housing of the device 2, which is provided with the reference number 10, is in the area of an interface 11, in which the data cable 3 is led out of the housing 10, a little way beyond the end of the data cable 3, more precisely its outer sheath , Covered in the plastic injection molding process, so that there is a medium-tight and permanent connection between the data cable 3 and the housing 10 of the device 2 in the interface 11 results.

Such a medium-tight and non-detachable connection can also be realized in the area of an interface 12, where the other end of the data cable 3 is led into the housing of the subscriber 8.

Such a medium-tight and non-detachable connection can also be realized in the area of an interface 13 where one end of the data cable 4 is led out of the housing 10 of the device 2 . The same can also apply to the interfaces where the data cables 5 and/or 6 and/or 7 and/or more or fewer data cables are routed out of the housing 10 of the device 2 .

As in the case of the subscriber 8, the end of the data cable 4, which is led into the housing of the subscriber 9, can be realized in the area of a local interface 14 in the subscriber 9 in a media-tight and non-detachable manner by overmolding.

In a particularly advantageous manner, all interfaces 11, 12, 13 and the other interfaces at the two ends of the respective data cables 5 to 7 are implemented in a media-tight and non-detachable manner by overmoulding. In a particularly advantageous manner, all interfaces 11, 12, 13 and the other interfaces at the two ends of the respective data cables 5 to 7 are implemented in a media-tight and non-detachable manner by overmoulding. Of course, not all of these interfaces have to be implemented in a media-tight and inseparable manner by overmoulding with plastic, but some of the interfaces can also be designed as a plug-in connection, for example as a screw plug-in connection, as is known in the prior art.

reference list

1. Arrangement

2. Input-Output Device

3. Data cable

4. Data cable

5. Data cable

6. Data cable

7. Data cable

8. Participant

9. Participant

10. Housing

11. Interface

12. Interface

13. Interface

14. Interface

Claims

patent claims

1. Arrangement (1) for distributing data, comprising an input-output device (2) with at least two interfaces (11, 13) for transmitting data between the interfaces (11, 13) connected participants (8, 9) , wherein data cables (3, 4) are provided, via which each participant (8, 9) is connected to its associated interface (11, 13), characterized in that a housing of the input-output device (2). the housing is produced in a plastic injection molding process and at least one respective end area of the data cable (3, 4) is surrounded by the housing.

2. Arrangement (1) for distributing data, comprising an input-output device (2) with at least two interfaces (11, 13) for transmitting data between the interfaces (11, 13) connected participants (8, 9) , Data cables (3, 4) being provided, via which the respective one participant (8, 9) is connected to its associated interface (11, 13), characterized in that a housing of the input-output device (2) consists of is made of a metal material and that an interior area of the housing is cast with a plastic material, the plastic material extending over at least the respective end area of the data cable (3, 4).

3. Arrangement (1) for distributing data, comprising an input-output device (2) with at least two interfaces (11, 13) for transmitting data between the interfaces (11, 13) connected participants (8, 9) , Wherein data cables (3, 4) are provided, via which each of the participants (8, 9) to connected to its associated interface (11, 13), characterized in that a housing of the input/output device (2) is made of plastic and that an interior area of the housing is cast with a plastic material, the plastic material spreading over at least the respective End of the data cable (3, 4) extends.

4. Arrangement (1) according to claim 1, 2 or 3, characterized in that a housing of at least one of the participants (8, 9) is molded onto an end region of its associated data cable (3, 4).

5. Arrangement (1) according to Claim 1, 2, 3 or 4, characterized in that all data cables (3, 4) are surrounded by the housing of the input/output device (2) and the housings of all participants (8, 9 ) are molded onto the end area of their respectively associated data cable (3, 4).

6. A method for producing an arrangement (1) for distributing data, comprising an input/output device (2) with at least two interfaces (11, 13) for transmitting data between users connected to the interfaces (11, 13) ( 8, 9), data cables (3, 4) being provided, via which the respective one participant (8, 9) is connected to its associated interface (11, 13) on the finished input-output device (2), characterized characterized in that a housing of the input/output device (2) is produced in a plastic injection molding process and a respective end area of the data cable (3, 4) is surrounded by the housing.

7. A method for producing an arrangement (1) for distributing data, comprising an input/output device (2) with at least two interfaces (11, 13) for transmitting data between participants connected to the interfaces (11, 13) ( 8, 9), wherein data cables (3, 4) are provided, via which one Subscriber (8, 9) is connected to its associated interface (11, 13), characterized in that a housing of the input-output device (2) is made of a metal material and that an interior area of the housing is cast with a plastic material, the plastic material extending over at least the respective end area of the data cable (3, 4).

8. A method for producing an arrangement (1) for distributing data, comprising an input/output device (2) with at least two interfaces (11, 13) for transmitting data between users connected to the interfaces (11, 13) ( 8, 9), data cables (3, 4) being provided, via which the respective one participant (8, 9) is connected to its associated interface (11, 13), characterized in that a housing of the input-output device (2) is made of plastic and that an interior area of the housing is cast with a plastic material, the plastic material extending over at least the respective end area of the data cable (3, 4).

9. The method according to claim 6, 7 or 8, characterized in that a housing of at least one of the participants (8, 9) is molded onto an end region of its associated data cable (3, 4).

10. The method as claimed in claim 6, 7, 8 or 9, characterized in that the housings of all the participants (8, 9) are molded onto the end region of their respectively associated data cable (3, 4).