DE202008013288U1 - Device for stripping-free production of a connection to a flat cable and building bus system - Google Patents

Abstract

Apparatus for stripping-free production of a connection to a flat cable (4), which has at least one shielded data line (8) with one or more wires (9),
the device (1) having a housing for embracing the flat cable (4) with at least one upper part (3) and one lower part (2),
wherein it is equipped with a tapping device (46) which has at least one tap contact (10) which is suitable for the stripping-free penetration of shield (22) and insulation (24, 25) and for contacting a wire (9),
the tapping device (46) is configured in such a way that the connection is made by applying force to the tapping device (46) and a concomitant penetration of the tapping contact (10) into the flat cable (4),
in the housing at least one bus coupler and a sensor and / or an actuator and / or a data interface are arranged, and
a conductive connection between the sensor and / or the actuator and / or the data interface with the data line (8) through the tap contact ...

Description

The The present invention relates generally to terminal devices, and more particularly to a device for insulation-free manufacture a connection to a flat cable, the at least one shielded Data line with one or more wires and on a Building bus system with at least one such connection device and a flat cable.

Connection devices, with which a continuous flat cable without tearing of the wires and without removal of wire and cable insulation can be tapped, have been known for over 30 years. An early publication in this respect from the applicant's home is, for example, the German patent application DE-AS 2 206 187 , This publication was only about the tapping of power lines, so lines with unshielded wires. Tapped screws were used as tapping contacts. The connection was made by the connecting device with its housing - initially without the contact screws - placed on the cable and then the cable was also enclosed on the back of a housing plate. Finally, the tapping was done by the guided in the housing with internal threads contact screws were screwed into the flat cable. They penetrated with their tip first the outer insulation of the flat cable, then the respective core insulation, and finally penetrated with the tip in the head of each vein. This contacted the vein in question.

A further development of this basic form is from the EP 0 665 608 B1 known. Due to the use of digital processor controls in building installation technology, which had started in the meantime, the idea had arisen to tap data lines in a corresponding manner, in addition to power lines. In order to make it possible for the wires of the data line (which is, for example, a symmetrical pair line) to be at any desired longitudinal position of the cable with a tap contact, they are not twisted together, as is usual in such data lines parallel to each other in the median plane of the flat cable. In view of the lack of twist magnetic coupling, z. B. to keep within acceptable limits of the running in the same flat cable energy transmission cores, the data line to the outside, that is also shielded from the running in the flat cable energy transmission cores. The tapping takes place as in the above-mentioned DE-AS 2 206 187 by screwing in contact screws. So that the contact screws do not produce short circuits between the contacted wire conductors and the shield, they are equipped with a layer of insulating material on the shaft.

In the course of further development then matured the realization that the screwing in of individual contact screws causes a relatively high installation costs. For example, the DE 201 11 496 U1 and the corresponding one EP 1 276 173 A2 - according to which the preamble of claim 1 has been formulated - that from the above EP 0 665 608 B1 known tapping device to the effect that the former contact screws are now replaced by fixed in a housing plate "tapping spikes". The actual contacting process is no longer done by screwing individual contact screws, but - in one operation together for all tap contacts - by pressing the contact pins supporting the housing plate on the flat cable. As far as the taps serve to tap the data line, they are - analogous to the above EP 0 665 608 B1 - Provided with insulation on its shaft. Mentioned in the DE 201 11 496 U1 the problem that the shield could be pulled inward from the contact tip during piercing, thus causing a short circuit; as a countermeasure, a particularly acute-angled design of the respective contact mandrels is proposed (page 20, lines 28-32).

A further development in terms of impressing fixed in a housing plate arranged contact elements can be found in the WO 2005/057729 A1 That is, here for ease of Eindrückvorgangs a lever actuator is integrated into the housing. The housing plate is articulated on one side of the housing; with the help of a hinged on the other side of the housing fork lever, which engages in the housing, the housing plate can be pressed with the fixed contact elements with relatively little effort in a pivoting movement on the cable. This is about the contacting of flat cables, which have only high voltage wires.

Furthermore, the intelligent control system in building technology requires a bus system via which systems such as heating, lighting, air-conditioning and safety devices can be controlled. In EIB terminology, "trades" is the generic term for equipment that can be connected to and controlled by the building bus system. A well-known bus system is, for example, KNX, which has emerged from the EIB system. The KNX provides a bus line, actuators and sensors that exchange data with each other in the form of telegrams. Thus, for example, a temperature sensor measures a temperature and then sends a telegram to an actuator which, in response, for example, controls a shutter accordingly. Well-known act In the KNX standard, sensors and sensors are usually interconnected with round twisted pair cables, ie with twisted data cables. The connection of the actuators, sensors and other participants of the building bus system to the round Twister-Pair cable is complex.

Of the present invention is a problem (technical problem) the Provision of a simple and safe to install connection device of the type mentioned at the outset and the provision of a building bus system, the basis of such connection devices.

The The invention relates to devices according to the independent Claims 1 and 7 and a system according to the independent Claim 19. Further optional embodiments of the Invention can be found in the dependent claims.

As already stated above, it is in building engineering known, actuators and sensors in a bus system for controlling Provide trades. As is known, actuators and Sensors with connection devices for making a connection be connected to a flat cable. The actuators and sensors are but separated from the connection device. With the below It is described in more detail connection device possible an actuator and / or sensor and / or a data interface in a device for stripping-free production of a connection to integrate with a flat cable. The flat cable has at least a shielded data cable with one or more wires. Optionally, the flat cable additionally has a power line with power lines on. The device further comprises a housing for embracing the flat cable, the at least one upper part and a lower part has. The top is optional over a Joint connected to the lower part. The device also has a Tapping device with at least one tap contact, the to Stripping-free penetration of shielding and insulation and suitable for contacting a wire. The tapping device is optionally partially integrated in the housing. So For example, the upper part of the housing a pressure plate have, on which the tapping contacts are arranged. The tapping device Is designed such that the preparation of the connection by Applying force to the tapping device and a concomitant Penetration of the tap contact in the flat cable takes place. Thereby Is it possible in a simple operation without additional Tool or other aids the connecting device easy and quickly attach to a flat cable. The actor and / or Sensor and / or the data interface that are in the housing, are connected to a bus coupler. By the tapping contact is then after mounting the connection device, a conductive connection between the sensor and / or the actuator and / or the data interface produced with the data line via the bus coupler. Of the Bus coupler serves as interface between actuator, sensor or data interface and the data line and includes, for example, a microprocessor and a memory in which small sequence programs are stored can and physical addresses and group addresses that for example, were assigned during a programming. Data signals (telegrams) can then receive over the data line and can be sent and over the data interface the participants are programmed in a building bus system.

Of the Sensor can be used as temperature sensor, wind speed sensor, radio receiver, Infrared sensor, brightness sensor, gas sensor, smoke sensor or motion sensor or the like may be formed. A sensor is thus very general an element that sends a telegram in response to an outside Influence, such as reception of electromagnetic radiation or measurement of temperature, smoke density, movement, wind force, humidity etc., generated and the telegram settles on the data line. For this purpose points the sensor optionally has a corresponding electronic intelligence For example, by means of a microprocessor ready. This intelligence can also be included in the bus coupler.

The actuator is used to control an electrical load and optionally has a corresponding power output, for example, not only to control the electrical load directly, but also to provide power. Actuators can perform a variety of monitoring and switching functions. For example, actuators include load switching actuators, blind actuators, dimming actuators, binary input actuators, and the like. Load-switching actuators are characterized, for example, by the fact that they can switch electrical consumption or one or more groups of electrical consumers. Venetian blind actuators are, for example, designed so that a blind drive is directly connected to them, so that the actuator can directly control the blind drive, in order, for example, to gradually open or close a blind. On the other hand, dimming actuators are used to control lighting or one or more groups of lighting. Actuators with binary input can, for example, process switching or keying signals or one can be used for heating monitoring. Thus, for example, an actuator with quadruple binary input process four switching or key signals independently and make appropriate monitoring and control functions (eg. Of alarm or heating systems). The actuator also optionally has a certain, for example, provided by a microprocessor, electronic intelligence, which also teilwei may be contained in the bus coupler.

If the sensor comprises a radio receiver, so this can For example, radio signals from a wireless light switch or come from another radio control, radio control or radio control, received and a corresponding data signal (telegram) on the Apply data line. This data signal can then be elsewhere - eg. be received by an actor who takes the appropriate action (eg switch on the light). By doing so leaves save wiring between light switches and the bus system.

at some embodiments is in the connection device a data interface, eg a USB interface integrated, the one connection between an external data input device, For example, a portable computer, and the data line provides. This allows an operator using the external data input device Participants, such as actuators and sensors, in conjunction with the Data line stand, program.

at In some embodiments, the connection device comprises a power supply disposed in the housing of the terminal device is. In these embodiments, after assembly of Connection device on the flat cable, which has a data line and a Power line, a connection between the power supply and the data line made by the tap. The power supply then feeds itself from the power line - for example, by a tap contact (high current contact) of the tapping device the insulation of the flat cable penetrates without insulation and a Starkstromader the power line contacted. The power supply serves, for example, to supply sensors, actuators and / or data interfaces via the data line of a flat cable. In some embodiments the power supply via the data line exclusively via such Power supplies, while in others as additional Power supplies can be used, for example. If a central power supply can not supply enough power. The tapping device points Accordingly, tap contacts, for the stripping-free penetration insulation and - in the data line - the shielding and for contacting wires of the data or power line are suitable. The power supply therefore uses high current the power line, converts it and beaufschlägt the data line corresponding to the converted current or voltage. The power supply includes, for example, a transformer and converts the voltage applied to the power line (eg 230 V AC) eg. to a lower DC or AC voltage. These converted voltage then passes through the power supply at the the tap contact contacted wire of the data line. Consequently Optionally, an actuator can also be attached to the vein of the data line powered by voltage supplied voltage. In an optional embodiment, the power supply is in case of a malfunction a signal on the data line, so accordingly to respond to the malfunction. The power supply is also optionally designed, an overvoltage on the At least partially compensate data line. Furthermore the power supply can have overload protection. In some embodiments, the power supply a filter, for example a low-pass filter, on which the fault prevents data transmission in the data line.

In practice, it has also been shown that with piercing contacts on the type of the above DE 201 11 491 U1 the problem of avoiding short circuits between the shield and the conductors of the data wires is not optimally solved. Therefore, in practice until today for the contacting of shielded data wires still contact screws, in which a pulling in of the shield by means of a drill effect is reliably avoided. In some embodiments, pulling in of the shield when contacting data lines is avoided without requiring screwing in of the contact elements. This is based on the recognition that in connection devices with articulated pressure plate, which, for example, belongs to the tapping device and, for example, is arranged on the upper or lower part of the housing, a relative movement between tapping contact and flat cable in the cable longitudinal direction for pulling the shield can be responsible. In the case of an articulated pressure plate, an additional movement component relative to the cable in the direction of the joint may occur during the pivoting movement for pressing in the tapping contacts on an insulating flank lying proximally to the joint (eg if the joint lies above the contact end of the tapping contact). "Proximal" here means "facing the joint" (opposite: "distal", ie facing away from the joint). Proceeding from this, the invention reduces the problem of pulling in the shield in that this additional movement component can not even occur due to a displaceable arrangement of the tap contact. This measure has proven to be surprisingly effective.

The pivotal movement of the tap contact would therefore immobile mounting on the pressure plate to a component of the motion lead in the cable longitudinal direction. The tapping device comprises in optional embodiments, a pressure plate, which is hinged on one side, so that the impressions of the at least one tap contact by a pivoting movement of the pressure plate is made to the flat cable to the tapping contact is arranged so that the preparation of the connection by applying force to the pressure plate to the flat cable hin and a concomitant penetration of the tap contact is made in the flat cable.

at In some embodiments, the direction of this component of motion is so that the tap contact when penetrating into the flat cable to Joint would be offset. To avoid such Movement component when penetrating into the flat cable is the toggle contact in some embodiments slidably on the pressure plate arranged. For example, to avoid the aforementioned displacement towards the joint, in some embodiments, the direction the displacement so that the tap contact when entering the Flat cable is moved relative to the pressure plate away from the joint. To achieve such a shift, the tap contact is in the longitudinal direction of the pressure plate displaceable.

The Displacement of the tap contact is done, for example, by taking in the course of penetration: as soon as the free end of the cutting edge in engaging the sheath of the flat cable is a relative displacement the bleeder contact to the flat cable practically impossible (because of the intervention for this a relatively large force would be required). By the pivoting movement it comes to a relative movement between the flat cable and the pressure plate in the longitudinal direction. The early determination of the tap contact on the flat cable causes that the tapping contact is taken from the cable, so in the course the further pivoting of the relative to the pressure plate from the joint is moved away.

There the displacement path of the tap contact i. a. is limited to make sure that the bleed contact at the beginning the pivoting movement not already at the distal end of his displacement path stands, because this would be no (further) shift away from the joint. This would be z. B. conceivable that the operator involved in the installation prior to the "tapping" the toggle contact pushes it by hand to its proximal stop, so that it then stops Tapping has the freedom to move away from the joint with the cable. In some embodiments this is to a certain extent automated by the sliding tap contact in the pressure plate is subjected to force (eg spring loaded), so that he himself before penetration into the flat cable by the application of force (eg spring loading) in the end position of its displacement range which then moves in the course of penetration the tapping contact to prevent movement relative to the flat cable allowed in cable longitudinal direction. For example, the Tapping contact from a spring to the proximal stop of its displacement area applied. The imposition force is on the one hand sufficiently large, around the still freely movable (ie not yet intervening in the cable) To move tap contact on the pressure plate to the proximal stop, On the other hand, it is sufficiently small to engage the flat cable the entrainment of the tap contact by the relative movement of the cable to Otherwise, the tap contact would allow cut the cable lengthwise).

at In some embodiments, the tap contact is part of slidable carriage in the pressure plate. In some embodiments the tapping contact is made of a metal molding, the is surrounded at least in the flank region of insulating material. The metal molding is, for example, by casting and Punching / pressing with possibly subsequent machining, z. B. for sharpening the said cutting edge, produced.

at In some embodiments, a building bus system includes at least one flat cable, the at least one shielded data line with one or more wires and at least one power line having one or more power cores. Further includes the building bus system at least one of the above Connecting devices. The individual connection devices can in the building where the building bus system is installed is, arbitrarily - as needed - distributed and be used. Optionally includes the building bus system Connection devices with integrated actuator, with integrated Sensor, with integrated data interface and with integrated power supply. The power supply acts on the data line Voltage, as described above, and thus feeds, for example, an actuator and / or a sensor and / or a data interface over the Data line. Other actuators, sensors or data interfaces in the system, however, are fed via the power line in the flat cable. This is an extremely flexible, efficient and demand-oriented power supply of the individual Actuators and sensors in the system possible.

In some embodiments, the bus system meets the KNX or EIB standard, for example, so that a decentralized control is possible because in this system, the actuators and sensors have a corresponding "intelligence". Even through the use of a data interface is a decentralized Access to the data line and consequently to the entire bus system of the building is possible, which is very useful, for example, in building bus systems in large buildings.

By the use of the connection device with integrated power supply can be an extra in the building as needed Power supply can be provided. This is useful, for example, if extensions in a building already exist Power supply is no longer sufficient.

Optional can the individual sensors and actuators in the building system, eg via the data interface, programmed and coordinated with each other become. For example, a blind actuator can receive telegrams from a temperature and / or wind sensor and the associated blind drive up or drive down without it being a central control requirement.

Thereby, that the connecting devices without further tools on a Flat cables can be mounted and each component (actuator, sensor, Data interface) communicating via the data line, or a power supply already in the connection device integrated is an extremely simple, faster, flexible and demand-oriented construction of a building bus system possible for an intelligent building. By using flat cable is a simple and fast Cable laying guaranteed and through the connecting device eliminates a separation or transection of the flat cable. In addition, due to the integration of the actuator, sensor, the power supply or the data interface in the connection device additional connections between these components and the connection device.

Further Features go out for the expert reader the following detailed description of embodiments and the attached drawing.

embodiments The invention will now be described by way of example and with reference to FIGS attached drawing, in which:

1 is a perspective view of an embodiment of a connecting device in the open state;

2 a corresponding view of a cross section along the line II-II in 5 an embodiment with a slightly modified (namely, curved) contact shape;

3 and 4 Views according to the 1 respectively. 2 but are of the closed state of the terminal device;

5 a front view of the connecting device of 1 is in the open state;

6 shows a perspective top view of a pressure plate in the open state of the connection device;

7 a perspective top view of the pressure plate accordingly 6 , now, however, shows in the closed state; and

8th a schematic representation of a building bus system shows.

1 - 5 : General views of connecting devices

The 1 to 5 show overall perspective views ( 1 and 3 ) and side views ( 2 and 4 ) of embodiments of connection devices 1 which differ in the contact form. And that show 1 . 3 and 5 a connection device with tapping contacts with straight cutting edge, while the 2 and 4 represent another with curved cutting edges. The figures show the connecting device 1 in the open state ( 1 and 2 ) and when closed ( 3 and 4 ), as well as a front view of the opened state ( 5 ). The connection device 1 has a housing, which consists of a lower part 2 and a top 3 composed of a tapped flat cable between them 4 be able to record. Upper and lower part 2 . 3 are initially separate components that have complementary latching cams 19 ( 3 ) can be assembled so that they are about a common pivot axis 18 ( 2 ) from the open state ( 1 . 2 and 5 ) in a closed state ( 3 and 4 ) can be swiveled. The insides of the lower part 2 and the shell 3 each form a pressure plate 5 respectively. 6 leading to a tapping device 46 belong (see below).

The flat cable 4 ( 1 . 3 and 5 ) has an outer contour, which is opposite to a rotation of the flat cable 4 180 ° no symmetry. It has z. B. five in the median plane of the cable 4 juxtaposed power conductors 7 (For example, the three conductors of a three-phase system, the return conductor and a protective conductor), which together form a power line 45 form; in the same plane is also located on one side of the flat cable 4 a shielded data line 8th , It is her z. B. a symmetrical pair line, in the example shown two parallel non-twisted data wires 9 having. That one tenadern 9 are shared by a shield 22 which is, for example, a conductive (eg metallised) plastic film. Between the individual power lines 7 is located on the outside of the flat cable 4 each a longitudinal recess. However, no such deepening can be found between the data veins 9 because there is the shield 22 just goes; this already eliminates possible symmetry with respect to twisting of the cable 4 around 180 °. In addition, in the example shown, between the utmost energy supply vein 7 and the subsequent data line a particularly deep constriction exists; This also acts symmomenteseitend. The pressure plates 5 . 6 have a shape complementary to this cable outer contour shape, so that the flat cable 4 only in a certain orientation in the lower part 2 can be inserted, thus thus a "coding" of connection device 1 and cables 4 achieved. 5 provides a front view of the diagonally upstanding pressure plate 6 , Whose inner contour is complementary to the cable outer contour visible.

About the data wires 9 is in the pressure plate 6 of the top 3 one tap contact each 10 for the data wires 9 provided from the pressure plate 5 to the flat cable 4 protruding directed. The two tap contacts 10 are fixed (ie non-rotating and not movable) in the upper pressure plate 6 arranged. In cable longitudinal direction are the two tap contacts 10 Staggered to the with the impressions of the tap contacts 10 accompanying spreading of the data wires 9 in different places, seen in the cable longitudinal direction to distribute. (Note: In 5 are two bleed contacts 10 shown in 4 however, only one is shown).

Only stylized are in 1 and 5 Anzapfkontakte 20 for the power lines 7 shown. These are designed as non-insulated heavy current contacts, for example, in the manner of the WO 2005/057729 A1 known contacts, so that no further explanations follow. In the following, the term "tapping contacts" refers to the tap contacts 10 for the data line 8th ,

The connection device 1 has a partially integrated into the housing tapping device 46 on, to which also the pressure plate 6 with the tap contacts 10 respectively. 20 and with their help are both the tap contacts 10 as well as the power contacts 20 easily by a corresponding Kraftaufbeschlagung on a two-sided lever 11 into the corresponding wires of the flat cable. This is the top part 3 with the two-sided lever 11 equipped, that on a lever axis 12 at the top 3 hinged and this embraces fork-shaped. At the to the flat cable 4 pointing side of the lever 11 has this on both sides of the shell 3 one fork each 13 on that in a complementary fork recess 14 in the lower part 2 engage and provided there fork abutment 15 can take hold. At the of the flat cable 4 opposite side of the lever 11 this is with a handle 16 fitted.

The tap contacts 10 are not fixed in the pressure plate 6 arranged but in one in the pressure plate 6 longitudinally movable carriage 35 , The sled 35 is in one in the pressure plate 6 provided sliding guide in the longitudinal direction of the pressure plate 6 slidably mounted. The sled 35 is for example made of plastic, namely z. B. integrally with the isolation of the tap contact shown in more detail below 10 , Into that the sledge 35 including plastic part forming insulation is a contact piece 29 used in metal; it comes to the surface of the tapping contact at the free end of a cutting edge 10 ,

When closed ( 4 ) falls the longitudinal direction of the pressure plate 6 (ie the direction in which the tap contact 10 is displaceable) with the longitudinal direction of the flat cable 4 together. In the open state of the connection device 1 ( 2 ), the two directions do not coincide exactly, but differ by the pivot angle β of the connection device; in the projection of the pressure plate 6 on the flat cable 4 However, they also collapse when opened.

The sled 35 is limited in its longitudinal movement by stops, by a proximal stop 36 and a distal stop 37 , The maximum possible movement stroke between these two attacks is in 15 represented and designated x ₁ .

As will be explained in more detail below, is the carriage 35 Federbeaufschlagt so that it is in the open state of the connection device 1 in the in 2 illustrated starting position 38 located. And he is in this initial position 38 at the proximal stop 36 at.

The installation of a cable connection using the connection device 1 This is done in the following way: First, the flat cable 4 into the (still separate) lower part inserted. Then become lower part 2 and top 3 on her snap-in cams 19 for the formation of its pivot axis 19 together. Lower and upper parts are then initially in an open position, z. B. at an angle of 15 ° to each other, as in the 1 and 2 is shown. The operator now guides the fork 13 in the fork recess 14 and press the lever 11 down. This will - with force reduction due to the leverage - the upper part 3 on the flat cable 4 pressed so that the tap contacts 10 into the data line 8th penetrate and the data wires 9 contact, and the connection device 1 finally in the in the 3 and 4 shown closed state comes. At the same time, the heavy current contacts penetrate into the power cores 7 of the flat cable.

In the course of the closing movement of the approach contract penetrates 10 with its free end in the flat cable 4 a, and is in the course of the closing movement something in the distal direction relative to the pressure plate 6 moved, because otherwise he would be the cable 4 slit in the longitudinal direction. For this purpose, it is the tap contact 10 acting in the proximal direction spring force is smaller than the force acting on the contact slot force in the distal direction. After complete closure reaches the tap contact 10 in the 16 illustrated end position 39 , This end position 39 is not quite at the distal stop 37 ; Rather, here is a safety distance x _{2 is provided} to this stop to provide a certain tolerance for the displacement and thus avoid cable slit in the longitudinal direction in any case. The displacement path Δx is thus x ₁ - x ₂ .

The connection device 1 is thus already in its final state; one over the handle 16 to slide locking 17 prevents the connecting device 1 could return to their open position. The actual installation of a connection is thus - after inserting the cable and joining the device - without tools with only one hand movement feasible.

6 and 7 : Spring loading of the carriage

The 6 and 7 illustrate with a plan view of the pressure plate 6 an exemplary realization of the spring loading of the carriage 35 , To the movement of the carriage 35 relative to the pressure plate 6 The latter is with a clipping 40 equipped, in which the sled 35 is used. The longitudinal edges of the cutout 40 be from the sled 35 embraced and thus simultaneously form a longitudinal guide for this. At its distal end is at the sled 35 in one piece a springy tab 41 formed. This consists z. B., like the sled 35 , made of insulating plastic material. The springy flap 41 has in the unloaded state z. B. the form of a "V"; It can be elastically deformed into the shape of a "U", as in the 17 and 18 is shown. It supports with its free end to an abutment 42 at the distal edge of the clipping 40 is arranged. As long as no external forces on the slide 35 act, ie in the 17 illustrated open state of the connection device 1 , presses the springy tab 41 the sled 35 thus in the proximal direction to the proximal stop 36 so the sled 35 thus the in the 15 and 17 illustrated starting position 38 occupies. Acts however when closing the connection device 1 the contact's intervention 10 in the cable 4 resulting external force in the distal direction, so moves the carriage 35 under elastic deformation of the tab 41 in the distal direction, to the in the 16 and 18 shown end position 39 ,

In the in the 1 to 7 shown embodiments are multiple bleed contacts 10 together on a sledge 35 arranged. In contrast, in other embodiments, a plurality of independently displaceable carriages are provided (eg, in each case one carriage for each tap contact 10 ), in order to take account of differently sized displacement paths Δx, which will occur with relatively widely spaced tapping contacts (in the exemplary embodiments of FIGS 15 to 18 with shared slides, the difference in displacement was still considered negligible).

1 to 5 : Actuators and sensors

The connection device 1 points to the top 3 an outlet socket 21 , which is coded, for example according to one of the common industrial power systems (eg. B. Wieland ^{®, ®} or Wago Ensto ^®). In the data line 8th For example, it is a KNX, EIB, LON or CAN bus. In the shell 3 the connection device 1 is integrated a so-called actuator, so a device with one or more actuatable by control signal switches for the output socket 21 branching power conductors is equipped. In the present case, the actuator can exercise control and monitoring functions and the outgoing socket 21 represents a quadruple binary input. The control signals for switching on and off come as signals z. B. according to the KNX, EIB, LON or CAN standard on the data line 8th , With such an actuator z. B. electrical lighting and devices by control signals z. B. be remotely controlled by a building management center on and off. In another possible application is the connection device 1 designed as a sensor device, and is z. B. in the upper part 3 equipped with a suitable sensor (eg temperature sensor). The signals of this sensor can be transmitted via the data line 8th z. B. transmitted to a building control center. Alternatively or additionally, it is also possible external sensors or devices that provide measurement or status signals, via the outgoing socket 21 at the connection device 1 to join. This Si gnals are then from the connection device 1 in through the data line 8th fed bus formed.

One also in the top 3 In the case of the KNX standard, the integrated bus coupler serves, for example, as the interface between actuator and data line or sensor and data line.

In some embodiments, in the connection device 1 Actuators with various functions integrated. For example, load switching actuators can be integrated, which are characterized by a rated current per output of 16 A and a peak inrush current of 80 A and can switch electrical consuming. The switching functions themselves can be parameterized. Other actuators are used to control the blinds and are designed to control the blind drive directly, whereby the blind drive is connected directly to the actuator. Still other actuators are designed as a dimming actuator and can thus directly control the brightness of a lighting.

The sensors in the connection device 1 can be integrated, are, for example, a temperature sensor, wind speed meter, radio receiver, infrared sensor, brightness sensor, gas sensor, smoke sensor or motion sensor. The sensors are capable of sending telegrams (eg via a bus coupler) to the data line 8th be discontinued, which further processes a building management center or, as it is, for example, the case of the KNX standard, receives a corresponding actuator and further processed.

Furthermore, the connection device 1 be executed as a data interface by, for example, a USB interface in the upper part 3 is integrated and the plug output socket 21 configured as a USB-compatible port. The USB interface has a connection to the data line 8th via a bus coupler and the tap contact 10 ,

By integration of a power supply in the upper part 3 , The connection device can be used as a power supply, which is made of the power wires via a tap contact 20 feeds and the data line 8th over the tap contact 10 energized. For this purpose, the power supply contains, for example, a transformer for voltage conversion and a low-pass filter in order to prevent disturbances on the data line.

8th : Building bus system

Further functions of connection devices with integrated subscribers, such as actuators, sensors, data interface and power supply are now related to 8th FIG. 2 schematically illustrates an embodiment of a building bus system 50 that in a building 100 is installed.

The building bus system 50 includes a flat cable 4 , which is a "line" through different spaces 102 . 104 . 106 and 108 of the building 100 extends. The flat cable 4 indicates how, for example, in 1 shown is a data line 8th with veins 9 and a power line with power conductors 7 up and in the room 106 with a central power supply 52 connected, which acts on the power line a corresponding voltage. Optionally, the data cable of the flat cable 4 be fed by a central power supply. The bus system is a KNX / EIB decentralized building bus system that is standardized. In the case of the KNX / EIB building bus system, a central control system is not necessary since the subscribers of the bus system, such as actuators and sensors, exchange telegrams with one another, wherein each actuator or sensor has a unique address in the building system, for example in each case in a bus coupler in a connection device stored during programming of the system.

In the following, reference will be made to various subscribers of the building bus system, ie actuators, sensors, USB interfaces, power supplies, each in corresponding connection devices 1 , as detailed above, are integrated. For simplicity, the terminal device and its integrated actuators, sensors, etc. are denoted by the same reference numerals.

In the room 106 is a connection device 54 provided a USB interface 54 having. Via the USB interface 54 For example, an operator connects a computer and programs the subscribers (actuators, sensors, etc.) of the building bus system 50 , where the addresses are assigned during programming and small programs are stored in the bus couplers.

In the room 102 there is a connection device with a sensor 60 which is connected to a button for switching on a lighting. When the button is pressed, the integrated bus coupler sends the connection device 60 a telegram, the two connection devices 63 . 65 each with a dimming actuator to control a lighting received. The dimming actuators 63 . 65 supply themselves from the power line of the flat cable 4 and output a corresponding mains voltage of 230 volts AC, so that the lighting directly to the dimming actuators 63 . 65 can be connected. Depending on the programming, the sensor sends the connection device 60 , or the associated bus coupler, a telegram to a Group address, for example, in the bus couplers of the connection devices 63 and 65 is stored, so that both dimming actuators 63 . 65 each controlling a lighting in response to a button press of the button.

In room 104 there is a battery or solar powered wireless light sensor 68 which emits a radio telegram when actuated, which is a radio reception sensor in a connection device 62 receives. In the connection device 62 If, for example, additionally a media coupler is integrated, which then feeds a corresponding telegram into the data line. The media coupler receives its supply voltage via the data line 8th , A dimming actuator in a connection device 67 receives the telegram and then controls accordingly a lighting in the room 104 ,

A wind speed sensor in connection device 70 measures the current wind force and sends a telegram to the data line, which is a blind actuator in connection device 73 receives. The blind actuator 73 controls a blind 75 ie it drives it up, for example, when the wind strength exceeds a critical value.

Near the room 108 there is a connection device 77 with an integrated power supply that picks up voltage from the power line, converts and the data line of the flat cable 4 fed. The power supply 77 serves as additional power supply, so that an actuator with binary input, which is used for heating control and monitoring, in the connection device 80 can be supplied with voltage or power accordingly. In contrast, in other embodiments, the voltage is supplied via the data line 8th exclusively via connection devices with integrated power supply. The power supply 77 has an overload protection and an LED indicator that can signal a malfunction. Optional sends the power supply 77 in the event of a malfunction, a corresponding telegram, so that, for example, a control with display (not shown) displays the malfunction of the power supply on the display.

The described embodiments thus show connection devices, with which the stripping-free tapping of shielded data cables can be done in a simple and (short-circuit) safe manner and in which building bus system participants, such as actuators, sensors, Interfaces or power supplies are integrated.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - DE 2206187 [0002, 0003]
• - EP 0665608 B1 [0003, 0004, 0004]
• - DE 20111496 U1 [0004, 0004]
• - EP 1276173 A2 [0004]
• WO 2005/057729 A1 [0005, 0038]
• - DE 20111491 U1 [0015]

Claims (20)

Device for the stripping-free production of a connection to a flat cable ( 4 ), the at least one shielded data line ( 8th ) with one or more wires ( 9 ), the device ( 1 ) a housing for grasping the flat cable ( 4 ) with at least one upper part ( 3 ) and a lower part ( 2 ), with a tapping device ( 46 ) equipped with at least one tap contact ( 10 ), which is used for the stripping-free penetration of shielding ( 22 ) and insulation ( 24 . 25 ) and for contacting a wire ( 9 ), the tapping device ( 46 ) is configured such that the production of the terminal by applying force to the tapping device ( 46 ) and a concomitant intrusion of the tap contact ( 10 ) into the flat cable ( 4 ), in which housing at least one bus coupler and a sensor and / or an actuator and / or a data interface are arranged, and a conductive connection between the sensor and / or the actuator and / or the data interface with the data line ( 8th ) by the tapping contact ( 10 ) and is manufactured via the bus coupler. Apparatus according to claim 1, wherein the sensor a temperature sensor, wind speed meter, radio receiver, Infrared sensor, brightness sensor, gas sensor, smoke sensor or Motion sensor includes. Apparatus according to claim 1 or 2, wherein the Actuator a load switch actuator, blind actuator, dimming actuator, or binary input actuator includes. Device according to one of the preceding claims, in which the data interface comprises a USB interface. Device according to one of the preceding claims, wherein the power supply of the sensor and / or the actuator and / or the data interface via the data line ( 8th ) he follows. Device according to one of the preceding claims, wherein the power supply of the sensor and / or the actuator and / or data interface via a power line ( 45 ) of the flat cable ( 4 ) he follows. Device for the stripping-free production of a connection to a flat cable ( 4 ), the at least one shielded data line ( 8th ) with one or more wires ( 9 ) and at least one power line ( 45 ), the device ( 1 ) a housing for grasping the flat cable ( 4 ) with at least one upper part ( 3 ) and a lower part ( 2 ), with a tapping device ( 46 ), the tapping contacts ( 10 . 20 ) for the insulation-free penetration of insulation ( 24 . 25 ) and - in the data line - the shield ( 22 ) and for contacting wires ( 7 . 9 ) the data ( 8th ) and power line ( 45 ), the tapping device ( 46 ) is configured such that the production of the terminal by applying force to the tapping device ( 46 ) and a concomitant intrusion of the tapping contacts ( 10 . 20 ) into the flat cable ( 4 ), in the housing a power supply is arranged, the power supply power from the power line ( 45 ) and after conversion the data line ( 8th ). Apparatus according to claim 7, wherein the power supply has an overload protection. Device according to one of claims 7 or 8, in which the power supply in case of malfunction a signal on the data line there. Device according to one of claims 7 to 10, in which the power supply is designed, an overvoltage on the data line at least partially compensate. Device according to one of the preceding claims, in which the tap contact is designed to be electrically conductive at its free end and is equipped at its flank region with an insulation in order to prevent a short circuit between the wire to be contacted ( 9 ) and the shield ( 22 ) to avoid. Device according to one of the preceding claims, in which the tapping device ( 46 ) a pressure plate ( 6 ), which is articulated on one side, so that the impressions of the at least one bleed contact ( 10 ) by a pivoting movement of the pressure plate ( 6 ) to the flat cable ( 4 ), Apparatus according to claim 12, wherein the tap contact ( 10 ) displaceable on the pressure plate ( 6 ) is arranged to a relative movement between tapping contact ( 10 ) and flat cables ( 4 ) in the cable longitudinal direction when penetrating into the flat cable ( 4 ) to avoid. Apparatus according to claim 15, which is designed such that the tap contact ( 10 ) when penetrating into the flat cable ( 4 ) relative to the pressure plate ( 6 ) from the joint ( 18 ) is moved away. Device according to one of claims 13 or 14, in which the tap contact ( 10 ) in the Longitudinal direction of the pressure plate ( 6 ) is displaceable. Device according to one of claims 13 to 15, in which the displaceable tapping contact ( 10 ) is subjected to force in such a way that it prevents itself from penetrating the flat cable ( 4 ) is located by the application of force in the end position of its displacement area, which then during the penetration of a displacement of the tap contact to avoid movement relative to the flat cable ( 4 ) allowed in the cable longitudinal direction. Apparatus according to claim 16, wherein the application of force done by a spring. Device according to one of claims 11 to 17, in which the tap contact ( 10 ) Part of a in the pressure plate ( 6 ) sliding carriage ( 35 ). Building bus system, comprising: - at least one flat cable ( 4 ), the at least one shielded data line ( 8th ) with one or more wires ( 9 ) and at least one power line ( 45 ) with one or more power cores ( 7 ), and - at least one device according to one of claims 1 to 18. Building bus system according to claim 19, which comprises at least one device according to claim 5 with a sensor and / or actuator and / or a data interface and at least one device according to claim 7 with a power supply ( 77 ), wherein the sensor and / or actuator and / or the data interface by the power supply ( 77 ) via the data line ( 8th ) is fed.