EP1518812B1 - Elevator shaft wiring - Google Patents

Abstract

The elevator shaft cabling uses a hybrid ribbon cable (4) which incorporates at least one data line (8) and a door security circuit, at least one wire (11) of which is interrupted at each termination device (14) provided along the length of the hybrid ribbon cable, the termination device contacting both the data line and the door security circuit, e.g. together with a low voltage supply line (9). An independent claim for an elevator shaft cabling installation system is also included.

Description

FIELD OF THE INVENTION

The present invention relates generally to hoistway cabling and, for example, to hoistway cabling with a hybrid flat cable and terminal devices, and to an elevator hoist cabling installation system.

BACKGROUND OF THE INVENTION

In the cabling of elevator systems, on the one hand, the elevator car has to be connected to supply and control lines, which usually takes place by means of a movable cable hanging, for example, under the elevator car. On the other hand, elevator wiring usually also includes one or more cables installed in the hoistway stationary and running from floor to floor. They serve on each floor the connection of elevator door sensors, elevator door actuators and / or on-store elevator request and elevator signaling devices (with which an elevator user can signal a driving request and information about the acceptance of the driving desire, the current location of the elevator, the direction of travel of the elevator, etc. receives). For these purposes, usually a data bus line and a low voltage supply line are installed in the elevator shaft. Door security information may be transmitted coded over the data bus. In some installations, the elevator shaft also has its own door safety circuit installed. The latter connects in series connection the located on each floor at the respective elevator door door switch, which are open with the elevator door open and closed when closed, and thus interrupt the door safety circuit when one of the elevator doors is open. Sometimes, instead of a data bus - as in the past - a single-wire harness is used for each connected device; In some cases, mixed forms are common in which some devices are connected individually, others via a data bus, so that then a wiring harness with individual wires and a data bus is installed. In some installations, a power cable (typically for mains supply voltage, for example, 220 volts AC) is laid in the shaft, which typically without Geschoßabzweigungen from Wellhead to the pit passes (and for example a safety shutdown of the elevator when driving over the top floor is used), in some installations but also can have branches on the floors for the supply of projectiles with heavy current. Finally, in the elevator shaft often runs a supply line for a shaft lighting, which supplies along the shaft distributed lights.

Conventionally, the individual cables are combined to form one or more wire harnesses, which are either built individually on site during construction of an elevator, or prefabricated by the manufacturer or workshop and then installed and connected on site in the elevator shaft only.

From EP 0 187 876 B1 an elevator installation system is known in which a data cable formed by a flat cable is provided with a two-wire power supply for installation in the elevator shaft which is contacted on each floor by means of connectors with cutting tips and connected to floor-level modules , It is mentioned that three wires of the data line are available for the transmission of three special signals, such as "fire brigade", "special drive", and "output signals of a door monitoring". The latter are likely to be special signals for maintenance on doors.

From US 6,357,555 B1 prefabricated door cabling for each floor are known. To connect the wiring of the individual floors, the door cabling are each equipped with a suitable plug and a suitable socket on each leading to the neighboring floors line.

From EP 1 321 423, according to which the preamble of claim 1 has been formulated, a hoistway cabling with a flat cable is known. A door safety circuit guided in it can be interrupted during installation with the aid of an installation tool; With this tool, switch connection lines can also be contacted with the ends of the door safety circuit at the point of interruption by welding or pressing.

The prior art discussed below does not relate to elevator installation technology. For example, EP 0 460 038 B1 describes a bus flat cable with associated connection devices. One of the wires is used for the serial connection of devices, and must therefore be interrupted at each connection device and to contact on both sides by the connecting device. Other wires, to which devices are to be connected in parallel, run uninterrupted in the connection devices and are each tapped by means of the connection devices. In order to ensure interruption of the serial connection line in each connection device, the connection devices between the two serial taps are equipped with a spike-like projection which only allow the connection device to be placed on the flat cable if the serial line has previously been interrupted at the corresponding point.

EP 0 991 139 A1 describes a similar connection device into which a cutting device for the wire to be cut is integrated. The separation of the wire takes place hereby when placing the connecting device.

Tapping devices for hybrid flat cables are known from EP 0 665 608 A2 and DE 201 11 496 U1. In the former publication, the tapping of the wires is carried by provided with contact points screws, which are screwed into the core insulation. In the latter document, the contacting is done by fixed in the cover of the terminal device contact pins, which are pressed during assembly of the terminal device and pressing the lid through the wire insulation, whereupon they contact the wires.

SUMMARY OF THE INVENTION

The invention relates to a hoistway cabling, comprising: a hybrid flat cable which passes in the elevator shaft several or all floors of the elevator. The hybrid flat cable has at least one door safety circuit, of which at least one core is interrupted at projectiles. Dock outlet connections are mounted on the continuous hybrid flat cable and, with the hoistway cabling installed, remain seated on the hybrid flat cable and contact wires running therein. The hybrid flat cable also has at least one data line. The broken wire of the door safety circuit is interrupted in the region of the connecting device. The connection device contacts the data line and, at the point of interruption, the door safety circuit. It is designed so that they can be placed on the installation only on the hybrid flat cable if the safety circuit was previously interrupted at the point of attachment, or if it interrupts the safety circuit when placed on the hybrid flat cable.

In another aspect, the invention relates to a hoistway cabling installation system suitable for manufacturing hoistway cabling of the type mentioned above.

Other features are implicitly included in the disclosed products and methods, or will become apparent to those skilled in the art from the following detailed description of embodiments and the accompanying drawings.

DESCRIPTION OF THE DRAWING

• Fig. 1 schematisch eine Aufzugsschachtverkabelung in einem Aufzugsschacht zeigt;
• Fig. 2 schematisch eine andere Ausführungsform einer Aufzugsschachtverkabelung mit einem Hybrid-Flachkabel mit Starkstromadern zeigt;
• Fig. 3 die Unterbrechung des Türsicherheitskreises in den Anschlußvorrichtungen der Aufzugsschachtverkabelung veranschaulicht;
• Fig. 4 eine Querschnittansicht einer Ausführungsform einer Anschlußvorrichtung zeigt, welche auf ein Hybrid-Flachkabel mit bereits zuvor unterbrochenem Türsicherheitskreis aufsetzbar ist;
• Fig. 5 Querschnittansichten ähnlich Fig. 4 zeigt, jedoch von einer Ausführungsform, bei welcher der Türsicherheitskreis beim Aufsetzen der Anschlußvorrichtung unterbrochen wird;
• Fig. 6 Querschnittansichten verschiedener Ausführungsformen von Leiterkontaktierungen zeigt;
• Fig. 7 eine perspektivische Ansicht eines Ausschnitts eines Hybrid-Flachkabels zeigt, dessen Mantel zur leichteren Abmantelung des zu unterbrechenden Türsicherheitskreises perforiert ausgeführt ist;
• Fig. 8 eine schematische Draufsicht eines Hybrid-Flachkabels mit aufgeschnitten dargestelltem verdrillten Datenbus und Markierungen auf dem Kabelmantel zeigt;
• Fig. 9 eine Ansicht entsprechend Fig. 8 zeigt, jedoch von einer Ausführungsform mit Registrierungen statt Markierungen;
• Fig. 10 einen Querschnitt einer Ausführungsform eines Hybrid-Flachkabels zeigt, bei dem der Kabelmantel im Bereich des Datenbus leicht entfernbar ist;
• Fig. 11 eine perspektivische Ansicht eines Flachkabels und der einzelnen Teile einer Anschlußvorrichtung zeigt;
• Fig. 12 eine Ansicht ähnlich Fig. 11 zeigt, jedoch von einer Ausführungsform mit Schachtbeleuchtung.

Embodiments of the invention will now be described by way of example and with reference to the accompanying drawings, in which:

• Fig. 1 shows schematically an elevator shaft cabling in an elevator shaft;
• Fig. 2 shows schematically another embodiment of a hoistway cabling with a hybrid flat cable with power conductors;
• Fig. 3 illustrates the interruption of the door safety circuit in the connection devices of the hoistway cabling;
• Fig. 4 shows a cross-sectional view of an embodiment of a connection device which can be placed on a hybrid flat cable with a previously interrupted door safety circuit;
• Fig. 5 shows cross-sectional views similar to Fig. 4, but of an embodiment in which the door safety circuit when placing the connecting device is interrupted;
• Fig. 6 shows cross-sectional views of various embodiments of conductor contacts;
• 7 shows a perspective view of a section of a hybrid flat cable, the jacket of which is perforated for easier stripping of the door safety circuit to be interrupted;
• Fig. 8 is a schematic plan view of a hybrid flat cable with the twisted data bus shown cut away and marks on the cable sheath;
• Fig. 9 is a view corresponding to Fig. 8, but of an embodiment with registrations instead of markings;
• Fig. 10 shows a cross section of an embodiment of a hybrid flat cable in which the cable sheath in the region of the data bus is easily removable;
• Fig. 11 is a perspective view of a flat cable and the individual parts of a terminal device;
• Fig. 12 is a view similar to Fig. 11, but of a shaft lighting embodiment.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Fig. 1 schematically shows a hoistway cabling in a hoistway. Before a detailed description of FIG. 1, various explanations of the embodiments follow.

In the embodiments, the hybrid flat cable in the elevator shaft is laid so that it passes through several or all floors of the elevator. It has at least one data line and one door safety circuit. The hybrid flat cable has a substantially flat shape, as opposed to a round cable. However, the term "flat cable" does not imply that all the wires of the flat cable must lie in one plane (for example, the wires of a twisted data line are not in the plane defined by the flat cable). In the embodiments, however, are the center lines of the various lines (eg the imaginary center line in a twisted data line) in the plane spanned by the flat cable level. Of the Flat cable also does not imply that the cable surface needs to be level; Rather, in some embodiments, the cable has the form of circular cross-section individual cables which are connected by webs to a flat structure. The term "hybrid" in the embodiments expresses that the flat cable has at least two lines of different types, such as the said data line and the door safety circuit.

The terminal devices can be placed as projectile outlets on the continuous hybrid flat cable and set up for contacting some or all of the wires running therein. In the embodiments, the connection devices are designed so that they tap the continuous wires, without - apart from the safety circuit - a separation of these wires would be required.

In the case of the safety circuit, on the other hand, in order to achieve a series connection of the door switches located on each floor at the respective elevator door, there are other conditions, and indeed at least one wire of the door safety circuit is interrupted in the area of the connection device. The connection device contacted to achieve the series connection, the broken wire of the door safety circuit on both sides of the point of interruption.

In addition to said data line and said door safety circuit, in some embodiments, the hybrid cable also includes a low voltage power supply line. Some of the embodiments of the terminal device are constructed to also contact this low-voltage supply line. The said line is used, for example, to supply devices arranged on the individual projectiles, such as elevator door sensors, elevator door actuators, elevator requesting and signaling devices, control devices, etc.

In some embodiments, the hybrid flat cable also includes a power line. For example, the voltage (s) of a single-phase or three-phase power supply network with, for example, 220V / 380V rated voltage is applied to the high-voltage line. This line runs through certain installations from the pit to the shaft head of the elevator, without being tapped on individual floors. It is used, for example, the safety shutdown of the elevator when driving over the top floor, or the supply of arranged in the shaft head power devices. The connecting device is designed for these embodiments so that they provide no, or at least no compelling, contacting the power line, so that they can go through without tapping. In other embodiments, the (or each of) the terminal devices are configured to also contact the power line to provide power to devices or lighting devices disposed on the floors.

The door safety circuit is designed for low voltage (e.g., 20V or 48V) in some of the embodiments, and for the rated voltage of the power supply network (e.g., 220V) in other embodiments. In some of the embodiments, the one strand of the safety circuit which is to be interrupted in the region of the connection devices runs on the outside of the hybrid flat cable. This design facilitates the accessibility of the wire to be broken, e.g. in embodiments in which the interruption of the wire is done manually before the actual placement of the terminal device on the hybrid flat cable.

In some of the embodiments, with the wire of the safety circuit extending to the outside of the hybrid flat cable to be broken, the cable sheath has a perforation or notch between this wire and the other wires. This is used in the installation of the easy Entfembarkeit a cut piece of the wire in the area in which the connecting device to be attached to the cable. Subsequently, the connection device can be attached to the cable. In other embodiments, the cutting and / or contacting of the safety circuit is carried out through the cable sheath.

In some embodiments, the data line has at least two wires. It is, for example, a data line in which a pair of two equal, equally spaced wires form a symmetrical line. In some of the embodiments, the cores of a pair are parallel in a plane lying in a plane. In order to reduce asymmetric couplings into the data line, in other embodiments, the wires of a pair (or even several pairs, as in a Stemvierer line) are twisted together.

In some embodiments, the data line is contacted by penetrating both the cable sheath and the core insulation. In these embodiments, therefore, the cable sheath is not removed before attaching a connection device in the data line. On the other hand, in other embodiments remove the cable sheath at least on the data line; the contacting of the data line takes place here only by penetrating the core insulation. For easier removability of the cable sheath lying around the data line, this has a perforation or notch on the data line in some embodiments.

As mentioned, in some embodiments, the contacting of individual or all wires of the hybrid flat cable without stripping of wire insulation by means of penetration of the wire insulation. In some of these embodiments, the contacting of individual or all wires is done without removing the cable sheath by also penetrating the cable sheath. For this purpose, suitable penetration contacts are arranged on the connection device at the locations at which the respective cores to be contacted lie in the continuous flat cable. In order to ensure a clear definition of the relative position of connection device and flat cable, in some of the embodiments, the outer contour of the hybrid flat cable is complementary to the inner contour of the connection device; the contours are chosen so that the connection device can be contacted only in a unique position relative to the hybrid flat cable.

Certain types of Anzapfkontaktierung in lines whose cores relative to the outer contour of the flat cable in the cable longitudinal direction have no constant position, as is the case, for example, in the data line in embodiments with twisted wires certain difficulties. In some of the twisted data line embodiments, the hybrid flat cable, for example, on the cable sheath has repeating markers in the cable longitudinal direction, indicating for installation where to attach the connection device for contacting the twisted data line to the hybrid flat cable (or, in other embodiments). where the connection device is not to be set). Alternatively, in other embodiments, the hybrid flat cable has repetitive registrations in the cable longitudinal direction (for example in the form of elevations or depressions on the cable sheath) which allow the data line to be connected to the connection device only at suitable locations (which can also be realized thereby that the registration prohibits contacting at inappropriate places). The areas marked by the marking or predetermined by the registration, suitable for tapping, are for example (in the case of contacting in the direction transverse to the plane spanned by the flat cable) those points in the cable longitudinal direction at which the twisted wires are each parallel to the flat cable level.

While in some of the embodiments the wires of the twisted data lines are helically twisted together, in other embodiments a particular twist is realized in which the wires are parallel (ie untwisted) in sections, after which a twist of the two wires (eg 180 ° or a smaller angle, eg 90 °). The wires lie in the parallel sections (or in some of the parallel sections) in a plane suitable for contacting, for example in the flat cable plane or parallel thereto. In some of these embodiments, the above-mentioned markings or registrations are provided on the outside of the cable sheath, which specify where the parallel sections suitable for contacting are located (or - in embodiments in which the markings or registrations specify the positions not suitable for contacting - where these parallel sections not lying).

In other embodiments, with twisted data line (helically twisted or twisted with parallel sections), the hybrid flat cable has no markings or registrations of the type mentioned. Rather, here the contacting of the wires takes place after they have been stripped and placed in a suitable position for contacting. In some of these embodiments, the connection device has a holding contour in the region of the data line for this purpose, which holds the stripped cores in a defined position suitable for contacting.

In some embodiments, the safety circuit is to be interrupted before putting the terminal device on the hybrid cable, which can be done manually, for example. In order to ensure that the safety circuit is actually interrupted at the Aufsetzstelle to the terminal device, in some of these embodiments, the terminal device is designed so that - or required for the contacting part of the terminal device - during installation only on the hybrid flat cable can be placed if the safety circuit was previously interrupted at the point of attachment. For this purpose, for example, serve at a suitable location in the terminal device arranged insulating projection, which engages in the point of interruption of the relevant wire of the safety circuit, such that at not yet broken wire, the terminal device or serving for contacting part of the terminal device is not placed.

In other embodiments, however, it is not necessary to interrupt the safety circuit before placing the terminal device. Rather, here the connection device is designed so that it interrupts the safety circuit even when placed on the hybrid flat cable. In some of these embodiments, a stripping of the wire to be broken is required beforehand; the connecting device is thus only set to interrupt the stripped wire, but not the core with sheath. In other embodiments, no prior stripping of the conductor to be broken is required; the connecting device is able to interrupt the wire in the sheathed state. For example, the connecting device is equipped with a cutting blade and a displacement projection, which are formed so that when placing the terminal device (or its serving for contacting part) first the cutting knife cuts through the wire together with wire insulation and possibly cable sheath and then the displacement projection bends out the wire and intervene in the thus created point of interruption.

In some embodiments, the terminal device is constructed in two or more parts, wherein at least two parts of the terminal device are adapted to enclose the hybrid flat cable. In some embodiments, the contacting is then done by screwing or pushing through penetration contacts into the enclosed flat cable. In other embodiments, the penetration contacts are fixedly disposed in one of the parts of the terminal device; the contacting of the wires then takes place with the placement of this part on the flat cable and tensioning of this part on the other, the counterpart forming part of the connecting device.

In some embodiments, the connecting device is designed so that with the bracing of said parts and a wall mounting of the connecting device can be done. For example, used for clamping screws, which protrude on the bottom side of the connecting device and thus can be used for wall mounting.

For safety reasons, elevator shafts are usually equipped with shaft lighting. This is typically done by a separately laid in the shaft Cable which supplies luminaires arranged at regular intervals (eg in each storey or every other storey). In one of the present embodiments, however, the shaft lighting is integrated in the elevator shaft cabling described here. For this purpose, the lights are arranged on the connection devices themselves. The connection devices are designed so that the lights are connected to the supply of the connection device to the hybrid flat cable without additional power supply. For example, in the flat cable, a separate conductor circuit (low voltage or mains voltage) may be provided to supply the lights; alternatively, the lights may be powered by the general low voltage or power line in the flat cable; their connection and disconnection then takes place, for example, by control coupling to the data line. The luminaires are, for example, light-emitting diodes (LEDs), since they are particularly suitable for arrangement on the connecting device of the described installation system because of their relatively low power consumption, their low heat output and their low supply voltage.

Returning now to Fig. 1, this shows schematically an embodiment of a hoistway cabling 1 in an elevator shaft 2. The wiring 1 passes through several floors of the elevator, two of which are shown in Fig. 1 (these are designated 3 'and 3 "). The wiring 1 of the embodiment shown in Fig. 1 comprises a hybrid flat cable 4 and a separate power cable 5, for example in the form of a round cable The cables 4, 5 run in the elevator shaft 2 from the shaft pit 6 on the floors 3 '. , 3 "over to the shaft head 7. The hybrid flat cable 4 includes an example two-wire data line 8 (operated for example as a data bus), e.g. The two-pole low-voltage power supply line 9 and a door safety circuit 10. The latter is constituted by a door switch connecting conductor 11 and a return conductor 11 (connected to ground, for example).

The wires of said lines 8, 9, 10 are in the cable plane of the flat cable 4, wherein the head of the door safety circuit 10 outside and the data bus 8 and the low-voltage power supply line 9 are inside. The data bus 8 is shown in Fig. 1 with parallel wires. FIG. 1 thus simultaneously serves for the pictorial illustration of embodiments with parallel (ie non-twisted) data bus wires and as a schematic-abstract representation of embodiments with twisted data bus adem.

At the individual floors 3 ', 3 "is each a floor outlet 13', 13" provided. This is formed by an attached to the hybrid flat cable 4 connecting device 14 ', 14 "and out at this outgoing lines 15', 15". With the aid of the connecting device 14 ', 14 ", the wires of all the lines 9, 10, 11 of the flat cable 4 are tapped without interruption except for the door switch connecting conductor 11, the outgoing lines connected to these wires are thus branching lines, but the door switch connecting conductor 11 is in each of the connection devices 14 ', 14 "interrupted, and in the connection device 14', 14" is provided in front of and behind the point of interruption 16 ', 16 "a connection to a respective outlet line. These latter outgoing leads are respectively connected to the two terminals of a door switch 17 ', 17 "The door switches 17 are coupled to the doors of the elevator so that it is open when the door is open and closed when the door is closed is exemplified a case in which the door in the upper of the two projectiles 3 ', 3 "shown is open; Accordingly, the upper door switch 17 "is open, the lower 17 ', however, closed .. Thus, in the door safety circuit 10 is a series circuit of all door switches 17 realized, the door safety circuit 10 is interrupted, if - as in the case shown in Fig. 1 - not all doors An exit line 15 ', 15 "branched off from the return conductor 12 serves, for example The grounding of housings of the door switches 17 ', 17 ". The remaining outgoing lines 15', 15" connect elevator requesting and signaling devices 18 ', 18 "located in each floor 3', 3" to the data bus 8 and the low-voltage supply line 9.

For example, at the level of the shaft pit 6, an elevator control unit 19 is provided, which is connected to all lines 8, 9, 10 of the hybrid flat cable 4 and, in some embodiments, with the power cable 5. It controls the elevator and the devices 18 as a function of the signals received from them and whether the door safety circuit 10 is closed or interrupted.

Fig. 2 shows another embodiment of a hoistway cabling 1 similar to Fig. 1, but in which the power line (referred to here with 5 ') are not performed as a separate cable, but is part of the hybrid flat cable 4. Accordingly, the connection device 14 also surrounds the power line 5 '. In some embodiments this runs through the connection device 14 without tapping. In other embodiments, the connection device 14 is also designed for tapping the power line 5 '; the corresponding taps and branch lines are shown in dashed lines in Fig. 2.

Another difference from the embodiment of Fig. 1 (which is independent of the said training of the power line 5 as part of the hybrid flat cable 4), is that for the door safety circuit 10 is provided a separate from the ground line return conductor 12, which in Hybrid flat cable 4 here, for example, between the outer door switch connection conductor 11 and the data bus 8 is located.

3 shows the interruption of the door switch connecting conductor 11 in the connecting device 14. For this purpose, in the connection device 14 in the region of the interruption point 16, an insulation section 19 is provided, to the two sides of each a conductor contact 20 contacted the ends of the broken door switch connecting conductor 11 and connects to the outgoing lines 15.

4 shows a side sectional view of an embodiment of the connection device 14, which can only be placed on the hybrid flat cable 4 when the door switch connection conductor 11 has already been interrupted at the point of interruption 16. In the embodiment shown in Fig. 4, the connecting device 14 is constructed of two modules, which surround the flat cable 4 at the lower or upper flat cable side in the mounted state. These are a base part 21 and a tapping part 22, between which the flat cable 4 passes. For all wires to be contacted 22 conductor contacts are arranged in the tapping part, of which in the sectional side view of Fig. 4, only the two conductor contacts 20 for contacting the door switch connecting conductor 11 can be seen. The tapping part 22 of FIG. 4 is designed so that it can be placed only on the hybrid flat cable 4, if previously a piece of the door switch connecting conductor 11 was cut out at the relevant point of the flat cable 4, for example by means of a suitable double-side cutter , For this purpose, arranged in the tapping part 22 insulation path 19 is formed as a projection which engages in the interruption point 16 of the connecting conductor 11. In other embodiments, a corresponding projection is formed on the base part 21 instead of the tapping part 22, which already has an insert of the flat cable 4 in the base part 21 prohibits, if not previously said piece was cut out of the connecting conductor 11.

The conductor contacts 20 are, for example, U-shaped insulation displacement terminals, which surround the core 23 of the conductor to be contacted when placing the tapping part 22 on both sides, thereby cutting the core insulation and contacting the conductor running in the center of the core 23. Alternatively, the conductor contacts may be in the form of contact mandrels (for example according to DE 201 11 496) which penetrate the wire insulation and establish contact by fitting or even penetrating the contact wire with a contact tip. The said cutting terminals or Kontaktdome are e.g. firmly arranged in the tapping part 22. In other embodiments, the conductor contacts are formed as arranged in the tapping 22 screw contacts, which are for example screwed manually with a screwdriver after placing the tapping part 22 in the flat cable 4 and also penetrate the core insulation and contact the conductor with a contact tip (eg after in the EP 0 665 608 A1). All embodiments of conductor contacts 12 are preferably designed so that they can penetrate not only the respective core insulation, but also the jacket 24 of the flat cable 4. In these embodiments, therefore no stripping of the flat cable 4 is required. In other embodiments, the flat cable 4 is stripped off at least in the area of some of the lines before placing the terminal device 14. For example, the cable to be stripped may be the data bus 8 and / or the door switch connection conductor 11. For the continuous lines to be tapped 5 ', 8, 9, 12, one conductor contact 20 per connection device 14 (as shown in FIGS. 1 and 2) is sufficient, whereas for contacting the connection conductor 11 to be interrupted one conductor contact 20 in front of and behind each Insulation path 19 is provided in the connection device 14.

Fig. 5 shows another embodiment in which the connecting conductor 11 is interrupted only with the placement of the tapping part 22 on the inserted into the base part 21 flat cable 4. The Anzapfteil 22 is for this purpose equipped with a cutting blade 25, which is made for example of insulating plastic (and possibly can be made in one piece with the Anzapfteil 22). The isolation path 19 is at this embodiment designed as a chamfered projection; it not only serves to intervene in the interruption point 16 of the connecting conductor 11, but also this out when attaching the tapping part 22 from the flat cable level to the base part 21 out. For this purpose, the base part 21 has a recess 26 which is complementary to the insulation path 19 and thus likewise runs obliquely. Although in principle a simple cutting of the connecting conductor 11 is sufficient for its electrical isolation (eg when using a cutting blade made of lsoliermaterial), in the embodiment of FIG. 5 Thus, the connecting conductor is not only cut through, but the cut end with the help of the isolation gap 19 from the Cable level pressed into the recess 26 of the base part 21.

In some embodiments, the connection conductor 11 is severed in the stripped condition; In these embodiments, the cutting blade 25 only has the task of cutting through the connecting conductor 11 transversely. Accordingly, in these embodiments, a transverse to the direction of the connecting conductor 11 cutting knife 25 is sufficient. The embodiment shown in Fig. 5, however, is adapted to sever the connecting conductor 11 in the non-stripped state. In the illustrated embodiment, the cutting blade 25 has not only the said task of severing the connection conductor 11, but - to allow bending out of the severed cable end of the cable plane - also the task of the web-like connection of the cable sheath of the connection conductor 11 to the adjacent conductor in Cut longitudinal cable direction. For this purpose, the cutting blade has a substantially L-shaped cutting edge, wherein the longer leg of the "L" is arranged obliquely in the cable longitudinal direction.

5a and 5b illustrate the process of placing the tapping part 22 and the concomitant severing of the connecting conductor 11 in two different stages: Fig. 5a shows the situation at the beginning of the placement process, and Fig. 5b shows the situation with the tapping part 22 completely attached At the beginning, the cutting blade 25 penetrates into the connecting conductor 11 and the web-shaped connection of the jacket to the adjacent conductor and cuts both with increasing pressing of the tapping part 22. In the course of acting as Verdrängungsvorsprung insulation gap 19 presses one of the ends of the connecting conductor 11 at the cutting point in the recess 26. In addition, the conductor contacts 20 penetrate in the wire 23 and contact the conductor of the wire 23. In the final state (Fig. 5b), the wire 23 of the connecting conductor 11 is bent out of the cable plane so far that the severed wire ends are no longer directed to each other, which guarantees a safe electrical separation.

6a, 6b and 6c show different embodiments of conductor contacts 20 in partial side sectional views of terminal devices. The conductor contacts 20 are fixedly arranged in the tapping part 22 in two of the mentioned embodiments (namely according to FIGS. 6 a and 6 b), while the third embodiment (FIG. 6 c) provides a movable arrangement in the tapping part 22.

In the first embodiment according to FIG. 6a, the conductor contact 20 'is formed by a (perspectively illustrated) insulation displacement terminal. In the embodiment shown here, the cutting clamp surrounds the previously freed from the jacket 24 vein 23, wherein it cuts through the core insulation 27 in the course of placement of the tapping part 22 and so contacts the conductor 28 therein. In other embodiments, it is also possible to contact unsheathed wires with a cutting clamp of the type shown.

In the embodiment according to FIG. 6b, the conductor contact 20 "is designed as a contact mandrel, which penetrates the jacket 24 and the core insulation 27 when the tapping part 22 is placed and penetrates with its contact tip 41 into the conductor 28 and makes contact therewith. 6b, therefore, no sheathing is required, other embodiments similar to Fig. 6b are designed to contact previously sheathed cores 23, and accordingly, the contact mandrel does not need to penetrate the sheath 24 for them.

For the embodiment according to Fig. 6c, that stated with reference to Fig. 6b applies, with the proviso that in Fig. 6c as a conductor contact 20 "'a contact screw is provided, which sits in a threaded hole in the tapping part 22. In this embodiment takes place at herausgewarrter contact screw contacting not yet with the placement of the tapping part 22. Rather, the screw is intended to be screwed into the flat cable 4 after placing the tapping part 22, wherein it penetrates the jacket 24 and the core insulation 27 with its contact tip 41 and the Head 28 contacted.

The conductor contacts 20 ', 20 ", 20"' are electrically connected to the respectively associated outgoing lines 15 (Fig. 1) connected. The illustrated embodiments according to FIGS. 6 a to 6 c are suitable for tapping the various lines 5 ', 8, 9, 10. When using a shielded data bus 8, the conductor contact 20 to avoid a short circuit to the data bus shield above the area with which it contacts the conductor 28, be equipped with insulation (as described for example in DE 201 11 496 U1).

In order to enable simple manual production of the interruption point 16 (FIG. 4) in embodiments according to FIG. 4, in some embodiments, as shown in FIG. 7, the web-forming cable sheath 24 is located between the outer door switch connection conductor 11 and the remaining conductors of the hybrid flat cable 4 perforated in the cable longitudinal direction or, in other embodiments, weakened in cross-section (eg notched). The length of the perforation holes 42 or areas of weakness corresponds approximately to the length of the interruption point 16 to be created. By simply cutting through the unsheathed connecting conductor 11 at the two ends of such a perforation 42 (eg with the aid of a simple side cutter or a double-side cutter fitted to a suitable length) easily remove the conductor piece to be removed from the flat cable by means of the perforation 42. The terminal device 14 (e.g., according to the embodiment of Fig. 4) with the insulation path 19 engaging the split point can then be easily mounted.

8 is a plan view of a cutaway section of a hybrid flat cable 4 cut away from the data bus 8. Unlike the embodiments of FIGS. 1-3, the data bus 8 is external to the flat cable 4 (eg, at the location of the power line 5 'of FIG 3). In the embodiment shown in FIG. 8, the data bus 8 is a helically twisted pair line. If the tapping of the data bus 8 by penetration of conductor contacts 20, for example, in the direction perpendicular to the flat cable plane (ie perpendicular to the plane of Fig. 8), so are only those portions of the cable 4 for tapping, in which the two conductors of the data bus 8 side by side lie in the flat cable level, but not those areas where they are above each other. To indicate to the installer the tapping suitable locations of the flat cable 4, the cable sheath 24 is outside with suitable, repeating at regular intervals markings 29 provided. At the terminal device 14, a suitable countermarking is attached, wherein the connecting device 14 is to be positioned for example on the flat cable 4 in the longitudinal direction, that the two markings are aligned. Of course, the marker 29 may also be arranged at a different location relative to the twist of the data bus 8, for example, at those points where the two conductors are superimposed, or in any intermediate position. The desired result - namely a tapping of the data bus 8 only at the tapping point - is achieved by appropriate relative arrangement of the marking on the connecting device.

A similar view is shown in FIG. 9, but of another embodiment in which registrations 30 are provided on the outside of the cable sheath 24 instead of the markings. These have, for example, the form of projections at those points at which no tapping can take place because of a crossover of the conductors of the data bus 8. By suitable design of the connecting devices 14 - for example, the absence of complementary to the projections 30 recesses in the connecting devices 14 - ensures that the base member 21 and the tapping part 22 close only at those points around the flat cable 4, where the data bus Conductor contacts do not come to rest at a crossover point.

Another difference between Figs. 8 and 9 is that the conductors of the data bus 8 are not helically twisted (as in Fig. 8), but each extending over longer portions parallel and lying in the cable plane. This section-wise parallel course extends the tapable sections and thus facilitates the tapping of the data bus. Of course, markings according to FIG. 8 can also be used in the case of a data bus having parallel sections according to FIG. 9 and registrations according to FIG. 9, even in the case of a helically twisted data bus according to FIG. Both markings and registrations as shown in Figs. 8 and 9 permit tapping of the twisted data bus 8 through the jacket 24 of the flat cable 4, i. the jacket 24 may remain on the flat cable 4.

In contrast, in other embodiments (see, for example, the following FIG. 11), the cable jacket 24 is to be removed from the data bus 8 (also located on the outer edge of the cable 4) before the data bus 8 is tapped. In order to facilitate this, in the embodiment shown in Fig. 10 in cross-section of the cable sheath 24 is provided with a longitudinal notch 31 (or cross-sectional weakening). These facilitates a separation of lying over the data bus 8 cable sheath 24 before placing a connecting device 14. In order to easily separate the separated part of the cable sheath 24 of the cable sheath 24 on the remaining lines 10, possibly 5 ', 9, the hybrid flat cable 4, is also in the jacket 24 between the data bus 8 and the other lines 10, possibly 5 ', 9, a cross-section example, waist-shaped cross-sectional reduction formed. In other embodiments, this cross-sectional reduction is formed, for example, by perforations (similar to those shown in FIG. 7).

Fig. 11 shows an embodiment of a hybrid flat cable 4 and an associated terminal device 14 in the manner of an exploded view. The flat cable 4 has, in each case outboard, a door switch connection conductor 11 and a data bus 8 in the form of a twisted pair line. In between, run a return conductor 12 (which forms a door safety circuit together with the connecting conductor 11), a power line 5 '(which is formed here by four wires, for example for the transmission of three-phase alternating current eg 380 V) and a low-voltage supply line 9. The flat cable 4 is not uniformly thick in cross-section, but has between individual of the conductors (eg between the data bus 8 and the low-voltage supply line 9) webs of reduced thickness, and thus has a corresponding outer contour with depressions. This outer contour is asymmetrical with respect to a 180 ° twist of the cable 4 about the cable longitudinal axis and against a 180 ° twist, the beginning and end of the cable 4 reversed.

In the embodiment shown in FIG. 11, the connecting device 14 can be assembled from three parts, namely a base part 21, a tapping part 22 and a cover part 33. The two first-mentioned parts, ie the base part 21 and the tapping part 22, are designed to be in the assembled state To enclose the flat cable 4 tightly and to contact some or all of the wires running in it. For this purpose, the base part 21 and the tapping part 22 on an inner contour, which is the outer contour of the cable 4 is complementary. Due to the above-mentioned asymmetry of this outer contour, the connection device 14 can only be mounted on the flat cable 4 in one of four possible positions. In addition, it is ensured by an insulating section 19 in the form of a projection, similar to in Fig. 4, that the connection device 14 can only be mounted on the flat cable 4, if previously a corresponding section has been cut out of the door switch connection conductor 11. In contrast to the embodiment of Fig. 4 of the insulating section 19 forming projection is formed here on the base part 21 and extends into a corresponding recess 34 in the tapping part 22nd

In the embodiment shown in Fig. 11, the cable sheath 24 is to be removed over the data line 8 over a certain length, which is slightly shorter than the length of the connection device 14, at the connection point before the connection device 14 is attached. This makes it possible to unscrew the twisted wires of the data line 8 in this area and to insert in a holding contour 34 in the base part 21, which for example has the shape of three, parallel in the cable longitudinal direction blocks and thereby ensures a separation and a parallel position of said wires. A corresponding counter contour is provided in the tapping part 22 in some embodiments.

In the tapping part 22 different conductor contacts 20, fixed here in the form of U-shaped insulation displacement terminals. In the embodiment shown in FIG. 11, two of these conductor contacts 20 are located in front of and behind the recess 34 for contacting the interrupted connection conductor 11, as well as further conductor contacts 20 at the location of the in the holding contour 35 extending wires of the data bus 8 and the wires of the low-voltage supply line 9 (FIG. the retaining contour 35 has, for example, suitable slots to allow the passage of the insulation displacement terminals). Outgoing lines 15 each lead from the conductor contacts 20 to the outside.

The cover member 33 is equipped with two protruding sleeves 36 which engage in mounting the cover member 33 in complementary bores 37 in the tapping part 22 and base member 21 and thereby for centering the three parts 21, 22, 33 and, with slight compression of these parts, a ensure correct relative positioning of flat cable 4 and connector 14 already before the conductor contacts 20 fully penetrate into the flat cable 4. When using long screws, which protrude from the base part 21 in the sleeves 36 below, the wall mounting and the bracing of the connecting device 14 can be done in one operation. Namely, the lid member 23 presses by screwing said screws and tightening in the pad (eg the elevator shaft wall) the tapping part 22 fixed to the base member 21 and extending between these flat cable 4, whereby the - already properly positioned - Conductor contacts 20 penetrate the cable sheath 24 and the respective core insulation and contact the conductor of the respective core. In this case, a seal 38 surrounding the contact area is also compressed, which is arranged, for example, in the base part 21, which prevents the penetration of water and dirt into the contact area.

FIG. 12 shows an embodiment similar to FIG. 11, but in which a lamp 39 is arranged on the lid part 33. This is formed for example by several (here: four) LEDs. To power the lamp 39, a separate pair of wires 40 is provided in the embodiment of FIG. The tapping part 22 is equipped with conductor contacts 20 'specifically for tapping this wire pair 40. However, the tapped with these conductor contacts 20 'voltage is not - as in the other conductor contacts 20 - led out through outlet lines; Rather, connectors 22 are provided on the cover part 33 facing the top of the Anzapfteils, which cooperate with corresponding connectors in the cover part 23. With the placement and screwing of the connecting device 14, the pair of wires 40 is tapped and said plug connection to the lamp 39 is made. Thus, the embodiment of Fig. 12 allows installation of a continuous hoistway lighting without the need for any additional installation effort for the shaft lighting, apart from the cable and terminal equipment shown.

The described embodiments thus provide hoistway cabling which can be installed with little work but can be adapted to individual conditions (e.g., different storey heights) without prefabrication.

Claims (18)

1. Lift shaft wiring, comprising:

   a hybrid flat cable (4), which in the lift shaft (2) passes through several or all storeys (3) of the lift,

   wherein the hybrid flat cable (4) comprises at least one door safety circuit (10), of which at least one wire (11) is interrupted at storeys,
   connection devices (14) for storey outlets (13), which are placed onto the continuous hybrid flat cable (4) and in the case of the installed lift shaft wiring remain placed on the hybrid flat cable and contact wires running therein,
   wherein the interrupted wire (11) of the door safety circuit (10) is interrupted in the vicinity of the connection device (14),
   characterised in that the hybrid flat cable (4) also has at least one data line (8), and the connection device (14) contacts the data line (8) and also, at the interruption site (16), the door safety circuit (10), with the connection device (14) being constructed so that during the installation it can only be placed onto the hybrid flat cable (4) if the safety circuit (10) has previously been interrupted at the positioning site, or so that it interrupts the safety circuit (1) when placed on the hybrid flat cable (4).
2. Lift shaft wiring according to Claim 1, in which the hybrid flat cable (4) also has a low-voltage supply line (9), and the connection device (14) also contacts the low-voltage supply line (9).
3. Lift shaft wiring according to Claim 1 or 2, in which the hybrid flat cable (4) also has a high-voltage line (5').
4. Lift shaft wiring according to one of Claims 1 to 3, in which the wire (11) of the safety circuit (10) which is interrupted runs on the outside of the hybrid flat cable (4).
5. Lift shaft wiring according to Claim 4, in which the hybrid flat cable (4) comprises a cable sheath (24), and where the cable sheath (24) between the externally running wire (11) of the safety circuit (10) and the remaining wires comprises a perforation (42) or notching which during the installation serves for ease of removal of the cable sheath (24) lying around this wire (11) in the vicinity of the connection device (14).
6. Lift shaft wiring according to one of Claims 1 to 5, in which the data line (8) comprises at least two wires that run parallel to each other.
7. Lift shaft wiring according to one of Claims 1 to 5, in which the data line (8) comprises at least two wires which are twisted together.
8. Lift shaft wiring according to one of Claims 1 to 7, in which the hybrid flat cable (4) comprises a cable sheath (24), and where the cable sheath (24) at the data line (8) comprises notching (31) or a perforation which during installation serves for ease of removal of the cable sheath (24) lying around the data line (8).
9. Lift shaft wiring according to Claim 7 or 8, in which the wires of the data line (8) run parallel in sections of the hybrid flat cable (4), with the wires in the parallel sections lying in the area formed by the hybrid flat cable (4) or in a plane parallel thereto.
10. Lift shaft cabling according to one of Claims 7 to 9, in which the hybrid flat cable (3) comprises marks (29) or register marks (31), which for the installation indicate where the connection device (14) is to be placed on the hybrid flat cable (4) for the contacting of the data line (8) or - in the case of register marks (31) - which allow a contacting of the data line (8) with the connection device (14) just at the suitable places.
11. Lift shaft wiring according to one of Claims 1 to 10, in which the outer contour of the hybrid flat cable (4) is complementary to the inner contour of the connection device (14) and the contours are chosen so that the connection device (14) can only be contacted in a definite position in relation to the hybrid flat cable (4).
12. Lift shaft wiring according to Claim 11, in which the connection device (14) is constructed so that it contacts wires of the hybrid flat cable (4) without stripping off wire insulation (27) by means of piercing the wire insulation (27).
13. Lift shaft wiring according to one of Claims 1 to 12, in which the connection device (14) in the vicinity of the data line (8) comprises a retaining contour (35), which holds stripped wires of the data line (8) in a defined position suitable for contacting.
14. Lift shaft wiring according to one of Claims 3 to 13, in which the connection device (14) provides no contacting or no compulsory contacting of the high-voltage line (5'), so that this passes through without tapping.
15. Lift shaft wiring according to one of Claims 1 to 14, in which the connection device (14) is constructed in two or more parts, and contacting takes place by enclosing the hybrid flat cable (4) with at least two parts (21, 22) of the connecting device (14) and bracing these parts.
16. Lift shaft wiring according to Claim 15, in which the connection device (14) is constructed so that a wall mounting of the connection device (14) can also take place with the bracing.
17. Lift shaft wiring according to one of Claims 1 to 16, in which light fixtures (39) are disposed on the connection devices (14) for the illumination of the shaft, with the connection devices (14) being constructed so that with the installation of the connection device (14) on the hybrid flat cable (4) the light fixtures (39) are connected to the power supply without additional installation.
18. Lift shaft wiring installation system, constructed to produce lift shaft wiring according to one of Claims 1 to 17.

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