EP3137361A1 - Coil device for an electromagnetic track brake for a rail vehicle, magnetic track brake for a rail vehicle, and method for mounting at least one connection cable of a coil of an electromagnetic track brake for a rail vehicle - Google Patents

Abstract

The invention relates to a coil device (310) for an electromagnetic track brake for a rail vehicle. The coil device (310) has a winding wire (420), which has a first end (421) and a second end (422). The coil device (310) is characterized in that the first end (421) of the winding wire (420) is formed as a first coil connection for establishing an electrically conductive joint connection to a first connection cable (301) and/or the second end (422) of the winding wire (420) is formed as a second coil connection for establishing an electrically conductive joint connection to a second connection cable (302).

Description

 Coil device for an electromagnetic rail brake for a rail vehicle, magnetic rail brake for a rail vehicle and method for mounting at least one connecting cable of a coil of an electromagnetic rail brake for a rail vehicle

The present invention relates to a coil device for an electromagnetic rail brake for a rail vehicle, to a magnetic rail brake for a rail vehicle and to a method for mounting at least one connection cable of a coil of an electromagnetic rail brake for a rail vehicle.

In the case of an electromagnetic rail brake, its coil can usually be connected to a connecting cable via a metal sheet connected to a coil winding wire, a connecting pin and a cable lug which can be fixed to the connecting pin. In DE 10 2004 018 010 B3 a magnetic rail brake device of a rail vehicle is shown.

It is the object of the present invention to provide an improved coil brake device for a railway rail electromagnetic brake, an improved rail vehicle magnetic brake, and an improved method of mounting at least one connection cable of an electromagnetic rail brake coil for a rail vehicle.

This object is achieved by a rail brake electromagnetic rail brake device, a rail vehicle magnetic rail brake, and a method of mounting at least one connection cable of a rail brake electromagnetic rail brake according to the main claims. Advantageous embodiments emerge from the respective subclaims and the following description. In particular, according to embodiments of the present invention, in the case of an electromagnetic rail brake, a winding wire of a coil can be connected directly to a coil. be mechanically and electrically connected to the final cable. Thus, in particular a direct electrical connection between the connecting cable and winding wire of the coil by means of a joint connection or crimp, z. By crimping.

Advantageously, a favorable, installation space and component-saving coil connection can thus be provided. This results in a reduced fault potential and a minimization of potential electrical contact resistance. In addition to saving space required, expenses and parts requirements may advantageously in particular a risk of thermal damage due to cohesive connections, such. As soldering or welding, can be avoided.

The present invention provides a coil device for an electromagnetic rail brake for a rail vehicle, the coil device having a winding wire having a first end and a second end, characterized in that the first end of the winding wire as a first coil terminal for producing an electrically conductive joint connection is formed with a first connection cable and / or the second end of the winding wire as a second coil terminal for producing an electrically conductive joint connection with a second connecting cable is formed.

A rail vehicle can generally be understood to mean a track-bound vehicle, such as a locomotive, a multiple unit train, a drive car, a tram, a metro vehicle, a wagon such as a passenger and / or passenger coach or goods wagon or the like , The coil device may include an electrical coil having a plurality of windings of the winding wire. The winding wire can thus be wound in the coil device or coil to a plurality of windings or windings. The first end and the second end of the winding wire may be disposed in a terminal region of the coil device.

According to one embodiment, the first end of the winding wire and the second end of the winding wire may be arranged to cross each other. In this case, the first end of the winding wire and the second end of the winding wire can be arranged spaced from each other. Such an embodiment has the advantage that a crossover of the turns is well feasible and thus the last turn of the coil is complete, so that increases a flood. By means of such a coil device, a braking effect of an electromagnetic rail brake can be further increased. The present invention provides an electromagnetic rail brake for a rail vehicle, characterized in that the rail brake has at least one embodiment of the aforementioned coil device.

In connection with the electromagnetic rail brake, an embodiment of the above-mentioned coil device can be advantageously used or used to optimize a braking effect in a simplified and miniaturized structure. The electromagnetic rail brake may be a so-called eddy current brake. The coil device may be part of a rigid magnet or the like. The coil device can be movably attached to the rail vehicle by means of a suspension device. The electromagnetic rail brake may have at least one coil device.

According to one embodiment, the first connecting cable can be connected to the first coil connection by means of an electrically conductive joining connection between the first coil connection and one end of a first connection cable using a first ferrule and / or a first shrinking tube. Alternatively or additionally, the second connecting cable can be connected to the second coil connection by means of an electrically conductive joining connection between the second coil connection and one end of a second connection cable using a second ferrule and / or a second shrinking tube. Each of the compression sleeves can be designed to receive a connecting cable and / or a coil connection and to be joined or crimped with the same for producing an electrically conductive joint connection or crimp connection. Each of the heat shrink tubing may be formed to encase a joint to which a lead wire, a ferrule and a coil terminal are joined together. The

Shrink tubing may be formed from an electrically insulating material. Such an embodiment offers the advantage that it can be produced in a particularly simple and reliable manner by means of the ferrules, and can be inexpensively electrically insulated by means of the heat-shrinkable tubing. Also, the first ferrule and / or the second ferrule may have butt connectors or parallel connectors. In this case, a molded as a push connector ferrule may be formed to receive a coil terminal and an end of a connecting cable so that they abut end to end or axially to each other. A ferrule formed as a parallel connector may be formed to receive a coil terminal and an end of a terminal cable so that end portions thereof overlap. Such an embodiment offers the advantage that, depending on the conditions and requirements of a planned application, a suitable connector type can be selected.

The present invention provides a method for mounting at least one connection cable of a rail brake of an electromagnetic rail brake, characterized by a step of providing at least one embodiment of the aforementioned coil device, at least one first connection cable and at least one second connection cable and a step of manufacturing an electrically conductive joint connection between the first coil terminal and one end of the first connection cable and / or an electrically conductive joint connection between the second coil connection and one end of the second connection cable.

The method may be carried out using at least one embodiment of the aforementioned coil device in order to advantageously mount or, in particular, electrically contact the at least one connection cable of the coil of an electromagnetic rail brake.

According to an embodiment, in the step of manufacturing, the first coil terminal and the end of the first connection cable may be arranged overlapping or abutting one another. Alternatively or additionally, in the step of producing, the second coil connection and the end of the second connection cable can be arranged overlapping one another or abutting one another. Such an embodiment offers the advantage that, depending on the conditions and requirements of a planned application, a suitable type of connection can be carried out.

Furthermore, in the step of manufacturing, the first coil connection and the end of the first connection cable can be arranged in a first compression sleeve and connected to one another. to be joined. Alternatively or additionally, in the step of producing the second coil terminal and the end of the second connecting cable can be arranged in a second ferrule and joined together. Such an embodiment has the advantage that the electrically conductive or conductive joint connection can be made safely and inexpensively with little effort.

Also, in the manufacturing step, heat shrink tubing may be disposed on the coil terminals and the ends of the connection cables to electrically isolate the electrically conductive joints. In this case, each of the heat-shrinkable tubes can be arranged such that a joint at which a connection cable, a ferrule and a coil connection are joined together is enveloped by the shrink-on tube. Such an embodiment has the advantage that the electrically conductive joints can be electrically isolated in a simple and cost-effective manner. Preferred embodiments of the present invention will be explained in more detail below with reference to the accompanying drawings. It shows: a representation of a part of a coil of an electromagnetic

Rail brake;

Fig. 2 is a schematic representation of a winding wire of a coil;

3 shows a schematic representation of an electromagnetic rail brake with a coil device according to an exemplary embodiment of the present invention;

4 is an illustration of a part of a coil device of an electromagnetic rail brake according to an embodiment of the present invention;

Fig. 5 is an enlarged view of a portion of the coil apparatus of Fig. 4; a schematic representation of a winding wire of a coil device of an electromagnetic rail brake according to an embodiment of the present invention; and FIG. 7 is a flow chart of a method for mounting at least one

 Connecting cable of a coil of an electromagnetic rail brake according to an embodiment of the present invention. In the following description of the preferred embodiments of the present invention, the same or similar reference numerals are used for the elements shown in the various drawings and similar, and a repeated description of these elements will be omitted. Fig. 1 shows a representation of a portion of a coil 100 of an electromagnetic rail brake for a rail vehicle. Shown in Fig. 1 are each two of the following elements, wherein for reasons of space, only a connection cable 101, a

Heat shrink tube 102, a connecting pin 103, a hex nut 104, a cable lug 105, a further hex nut 106, a connecting plate 107 and a winding wire 108 are provided with reference numerals.

The connecting cable 101 is crimped with the tubular cable lug 105 and electrically insulated with the shrinking tube 102. The connecting cable 101 connected to the tubular cable lug 105 is screwed to a prefabricated connecting pin. The prefabricated pin consists of the terminal plate 107 and copper sheet, which is bolted to the pin 103 and soldered, the hex nut 104 and the other hex nut 106, which allow a frictional fixation of the tubular cable lug 105 with the pin 103, and the terminal plate 107, the allows a cohesive connection of the pre-assembled pin with the Wickel- wire 108.

FIG. 2 shows a schematic representation of a winding wire 108 of a coil. In particular, Fig. 2 symbolizes a so-called last turn of the winding wire 108 in the coil. The winding wire 108 is a winding wire such as the winding wire of the coil of the electromagnetic rail brake of Fig. 1. Shown are a The first end 201 of the winding wire 108 and a second end 202 of the winding wire 108. The first end 201 and the second end 202 are in this case arranged substantially parallel to each other, wherein the last turn of the winding wire 108 and the coil is incomplete. Thus, no crossing of the turns or the ends 201 and 202 of the winding wire 108 is realized.

3 shows a schematic representation of an electromagnetic rail brake for a rail vehicle with a coil device according to an exemplary embodiment of the present invention. Shown are the electromagnetic rail brake 300, a first connection cable 301, a second connection cable 302 and only by way of example a coil device 310. The first connection cable 301 and the second connection cable 302 are connected to the coil device 310. According to another embodiment, the electromagnetic rail brake 300 has a plurality of coil devices 310.

The electromagnetic rail brake 300 is in particular an eddy current brake or the like. The coil device 310 is for example part of a rigid magnet or the like. The coil device 300 has an electrical coil with a plurality of windings or windings of a winding wire. The electromagnetic rail brake 300 or the coil device 310 can be attached to the rail vehicle, for example, by means of a suspension device. The rail vehicle here is a track-bound vehicle, such as a locomotive, a trainset, a tram, a car or the like.

Although not explicitly shown in FIG. 3, the coil device 310 includes a winding wire having a first end and a second end. In this case, the first end of the winding wire is formed as a first coil terminal for producing an electrically conductive joint connection with a first connection cable and the second end of the winding wire is formed as a second coil terminal for producing an electrically conductive joint connection with a second connection cable. The coil device 310 will be discussed further below.

4 shows an illustration of part of a coil device of an electromagnetic rail brake for a rail vehicle according to an exemplary embodiment of the invention present invention. Shown are a first connection cable 301, a second connection cable 302, the coil device 310, a winding wire 420, a first end 421 of the winding wire 420 and a second end 422 of the winding wire 420. The coil device 310 is a coil device like the coil device Fig. 3.

The coil device 310 has the winding wire 420 with the first end 421 and the second end 422. The winding wire 420 is wound in the coil device 310 into a plurality of turns to realize a coil. The first end 421 and the second end 422 of the winding wire 420 are hereby arranged in a connection region of the coil device 310. The first end 421 of the winding wire 420 and the second end 422 of the winding wire 420 are arranged crossing each other. In this case, the first end 421 of the winding wire 420 is formed as a first coil terminal for producing a first electrically conductive joint connection with the first connection cable 301. The first end 421 of the winding wire 420 is electrically conductively connected to the first connecting cable 301 at a first joint. Further, the second end 422 of the winding wire 420 is formed as a second coil terminal for making a second electrically conductive joint with the second connection cable 302. The second end 422 of the winding wire 420 is electrically conductively connected to the second connecting cable 302 at a second joint. The first joint connection and the second joint connection are identical or identical. The joints or joints are described below using the example of the second joint or joint in Fig. 5.

5 shows an enlarged view of the second joint or joint of FIG. 4. Here, in FIG. 5, the second connection cable 302, the coil device 310 , the second end 422 of the winding wire, a crimp sleeve 530, and a shrink tube 540.

The crimping sleeve 530 is designed to produce, for producing the electrically conductive joint connection or crimped connection, a stripped end of a connecting cable, here the second connecting cable 302, and one end, here the second end 422, of the winding cable. to record wires and to be joined or squeezed with them. The heat-shrinkable tube 540 is designed to envelop the joint, here the second joint, where the second connecting cable 302 and the second end 422 of the winding wire are joined together using the ferrule 530, for the electrical insulation of the joint. The shrink tube 540 is formed of an electrically insulating material.

By means of the second joint connection or at the second joint, the second end 422 of the winding wire and the second connecting cable 302 are electrically conductively joined together. In this case, the second end 422 of the winding wire and a stripped end of the second connecting cable 302 are received in the ferrule 530 and joined or pressed together.

In this case, according to the embodiment of the present invention shown in FIG. 4 or FIG. 5, the ferrule 530 is formed as a butt connector. In this case, the second end 422 of the winding wire and the stripped end of the second connecting cable 301 are received in the ferrule 530 so that they abut each other axially or end to end.

According to another embodiment of the present invention, the ferrule 530 may be formed as a parallel connector. In this case, the second end 422 of the winding wire and the stripped end of the second connecting cable 301 may be received in the ferrule 530 so that end portions thereof overlap.

In other words, the second connection cable 302 is crimped directly by means of the ferrule 530 with the second end 422 of the winding wire. The ferrule 530 may be in the form of a parallel connector or butt connector. The shrink tubing 540 is configured to provide the electrical insulation of the

To allow pinch point or joint.

6 shows a schematic representation of a winding wire 420 of a coil device of an electromagnetic rail brake according to an embodiment of the present invention. In particular, FIG. 6 symbolizes a so-called last winding of the winding wire 420 in the coil device. The winding wire 420 is Shown are the first end 421 of the winding wire 420 and the second end 422 of the winding wire 420. Here, the first end 421 of the winding wire 420 are 420 and the second end 422 of the winding wire 420 are arranged crossing each other. Thus, a crossover of the turns or the ends 421 and 422 of the winding wire 420 is realized and the last turn of the coil device is complete, so that a flow of the same is increased.

7 shows a flowchart of a method 700 for mounting at least one connection cable of a coil of an electromagnetic rail brake according to an embodiment of the present invention. By carrying out the method 700, an electromagnetic rail brake such as the electromagnetic rail brake illustrated and described in FIG. 3 can be produced.

The method 700 has a step 710 of providing at least one coil device, at least one first connection cable and at least one second connection cable. In this case, the coil device has a winding wire with a first end and a second end. The first end of the winding wire is formed as a first coil terminal for making an electrically conductive joint connection with the first connection cable, and the second end of the coil wire is formed as a second coil terminal for establishing an electrically conductive joint connection with the second connection cable. The coil device is, for example, the coil device of one of FIGS. 3 to 5.

The method 700 also has a step 720 of producing an electrically conductive joining connection between the first coil connection and an end of the first connection cable and an electrically conductive joining connection between the second coil connection and one end of the second connection cable. Here, according to the embodiment of the present invention shown in FIG. 7, at step 720 of manufacturing, the first coil terminal and the end of the first connection cable are overlapped or abutted, and the second coil terminal and the end of the second connection cable are overlapped or abutted against each other , Further, in step 720 of FIG Producing the first coil terminal and the end of the first connecting cable arranged in a first ferrule and joined together and the second coil terminal and the end of the second connecting cable are arranged in a second ferrule and joined together. Also, in step 720 of manufacturing, heat shrink tubing is placed on the coil terminals and the ends of the connection cables to electrically isolate the electrically conductive joints.

The described embodiments are chosen only by way of example and can be combined with each other.

LIST OF REFERENCE NUMBERS

100 coil

 101 connection cable

 102 shrink tubing

 103 pin

 104 hex nut

 105 cable lug

 106 more hex nut

 107 Connecting plate

 108 winding wire

 201 first end of the winding wire

 202 second end of the winding wire

 300 electromagnetic rail brake

 301 first connection cable

 302 second connection cable

 310 coil device

 420 winding wire

 421 first end of the winding wire

 422 second end of the winding wire

 530 ferrule

 540 shrink tubing

 700 Method for mounting at least one connecting cable of a coil

710 step of providing

 720 step of manufacturing

Claims

Patent claims

Coil device (310) for an electromagnetic rail brake (300) for a rail vehicle, the coil device (310) having a winding wire (420) with a first end (421) and a second end (422), characterized in that the first end ( 421) of the winding wire (420) is formed as a first coil connection for producing an electrically conductive joint connection with a first connecting cable (301) and/or the second end (422) of the winding wire (420) as a second coil connection for producing an electrical conductive joint connection is formed with a second connecting cable (302).

Coil device (310) according to claim 1, characterized in that the first end (421) of the winding wire (420) and the second end (422) of the winding wire (420) are or can be arranged crossing one another.

Electromagnetic rail brake (300) for a rail vehicle, characterized in that the rail brake (300) has at least one coil device (310) according to one of the preceding claims.

Electromagnetic rail brake (300) according to claim 3, characterized in that at the first coil connection by means of an electrically conductive joint connection between the first coil connection and one end of a first connection cable (301) using a first crimp sleeve (530) and / or a first shrink tube ( 540) the first connection cable (301) is connected and/or to the second coil connection by means of an electrically conductive joint connection between the second coil connection and one end of a second connection cable (302) using a second crimp sleeve (530) and/or a second shrink tube ( 540) the second connection cable (302) is connected.

Electromagnetic rail brake (300) according to claim 4, characterized in that the first crimping sleeve (530) and/or the second crimping sleeve (530) have butt connectors or parallel connectors.

6. Method (700) for assembling at least one connecting cable (301, 302) of a coil device (310) of an electromagnetic rail brake (300) for a rail vehicle, characterized by a step (710) of providing at least the coil device (310) according to one of the claims 1 to 2, at least one first connection cable (301) and at least one second connection cable (302) and a step (720) of producing an electrically conductive joint connection between the first coil connection and one end of the first connection cable (301) and/or an electrically conductive one Joint connection between the second coil connection and one end of the second connection cable (302).

7. Method (700) according to claim 6, characterized in that in the step (720) of producing the first coil connection and the end of the first connection cable (301) are arranged overlapping or abutting one another and / or the second coil connection and the end of the second connection cable (302) can be arranged overlapping or abutting one another.

8. Method (700) according to one of claims 6 to 7, characterized in that in the step (720) of producing the first coil connection and the end of the first connecting cable (301) are arranged in a first crimp sleeve (530) and joined together and/or the second coil connection and the end of the second connection cable (302) are arranged in a second crimp sleeve (530) and joined together.

9. Method (700) according to one of claims 6 to 8, characterized in that in the step (720) of producing, shrink tubes (540) are arranged on the coil connections and the ends of the connecting cables (301, 302) in order to create the electrically conductive joint connections electrically insulated.