NL2034378B1 - Device for electrically connecting to at least one main core of main cores of a main cable - Google Patents

Abstract

Device for electrically connecting to at least one main core of main cores of a main cable, comprising: an essentially annular bracket, at least on its inside, provided with a recess for receiving the main cable in a position of use; at least one electrically conductive contact pin, extending radially away from an imaginary center of the recess, wherein the or each contact pin is provided with a sharp end directed towards the imaginary center of the recess, which sharp end is adapted to cut plastic as soon as the cutting pressure exceeds a threshold value; and at least one covering enclosing the at least one contact pin, formed from an electrically insulating material, preferably plastic, and provided with a pointed end directed towards the imaginary center of the recess, wherein the at least one covering is designed to remain in the condition of use to be pierced by the or each sharp end of the at least one contact pin, in particular at its or their pointed end.

Description

Device for electrically connecting to at least one main core of main cores of a main cable

The present invention relates to the electrical connection to at least one main core of main cores of a main cable. Specific embodiments relate to a device for determining the position and nature of main cores of a main cable, a device for determining the nature of main cores of a main cable, a system for determining the position and nature of main cores of a main cable, the use of such a device or system for determining the position and nature, or a nature, of main cores of a main cable, and a device for electrically connecting such a main core.

For certain purposes, such as the installation of a house branch joint, i.e. a joint that branches a branch cable from a main electrical cable to supply electrical supply to a building, such as a house or commercial premises, it is useful to specify the position and nature of the main conductors. determine the main cable. There are typically four different main cores in such a main cable, but sometimes more, e.g. 6 or less, and the branch must connect properly to each main core. It is particularly important that the contact with each main core of the main cable is sufficiently centered in that main core, to avoid failed contact, and in addition the branch must correspond to the nature, or color, of the main core, in order to maintain the correct mutual voltages. between the main cores of the branch cable.

The common approach to determining the position and nature of main cores of a conductor involves stripping the main cable to expose the main cores; mounting a clamp on the main wires; wrapping the clamp and filling the exposed portion of the main cable (typically with resin) to repair that exposed portion.

This common approach has at least the following disadvantages: - It is labor intensive, because it requires the main cable to be stripped and, after branching, complicated and filled with, for example, resin.

- It does not provide sufficient safety, because several conductors are exposed during the operation, especially during the stripping of the main cable. - It does not provide sufficient guarantee of quality, because quality depends largely on how well an installer applies the branch sleeve, and in addition, stripping the main cable makes its structure and the precise position of the main cores in the main cable less stable.

It is an object of the present invention to solve at least one or more of these disadvantages.

To this end, the present invention provides a device for determining the position and nature of main cores of a main cable, wherein the device is rotatable around the main cable in a state of use, comprising: - at least one conductor that is electrically insulated from the main cores, wherein the or each conductor is designed to be located at an outer wall of the main cable in the position of use, wherein the or each conductor extends along a longitudinal direction that shares at least a longitudinal component with a longitudinal direction of the main cable; - a voltage meter designed to measure a voltage or voltages between the or each conductor and a predetermined reference point, which voltage or voltages are generated by electrostatic influence of charge carriers in the main conductors when the or each conductor is in the condition of use at the outer wall of the main cable; and - a microcontroller adapted to detect a maximum amplitude or minimum amplitude of the measured voltage or voltages when the device is rotated around the main cable in the operating condition, and adapted to determine the locations of the main conductors on the basis of the detected maximum amplitude or minimum amplitude .

This arrangement overcomes the disadvantages described above because it no longer requires the main cable to be stripped, convoluted and filled with resin, because none of the conductive elements inside the main cable are exposed, and because the stability of the structure of the main cable is retained.

Moreover, this device is convenient and quickly applicable, with a minimum of training for an operator, which makes the application possibilities very numerous.

Note that the nature of a main core of a main cable typically corresponds to the color of that main core, but in a strict sense the nature is actually determined by the ratio of the alternating electrical voltage to that in the other main cores. The skilled person will be able to make this distinction without any problems, and therefore in the present text, “nature” will suffice.

Also note that it is implicitly assumed that a power source is available to the microcontroller. This can simply be its own battery, but a connection can also be provided for connection to an external energy source. In another embodiment, a parasitic energy system can even be provided, which is adapted to drive the microcontroller based on energy harvested from the environment, preferably from the electrical energy present in the main cable.

In practical embodiments, the predetermined reference point can be, for example, an internal ground of the device itself, or, for example, the earth screen of the main cable, or, for example, an earth stake driven into the ground, etc.

In one embodiment, the at least one conductor has at least two conductors, designed to be located on opposite sides of the outer wall in the condition of use.

This allows you to rotate only 180 degrees.

In one embodiment, the at least one conductor has three conductors, designed to be located on three sides of the outer wall in the condition of use, which three sides are either essentially perpendicular to each other or essentially 120° apart.

In one embodiment, the at least one conductor has four conductors, designed to be located on four sides of the outer wall in the condition of use, which four sides are essentially at right angles to each other.

In one embodiment, the at least one conductor has six conductors, designed to be located on six sides of the outer wall in the condition of use, which six sides are essentially 60° apart from each other.

In one embodiment, the or each conductor extends along a longitudinal direction that corresponds to an estimated conventional winding pitch of the main cores.

The skilled person will realize that the conventional winding pitch can be determined on the basis of applicable norms and standards, such as standard NEN 3616:2001 nl in

The Netherlands for the definition of these types of main cables. Even if in practice a main cable were to deviate from the conventions defined in such norms and standards, the estimated conventional winding pitch provides a suitable approximation, at least to start with.

In this way the most efficient electrostatic influence can be obtained.

In one embodiment, the device comprises an essentially annular recess, designed to receive the main cable.

In this way the device can be connected closely to the main cable.

In a further developed embodiment, the device comprises two complementary designed jaw parts that, in use, form the recess for receiving the main cable.

In this way the operator can suffice with access from only one direction; it does not need to be able to reach the “back” or “bottom” of the main cable.

In a further developed embodiment, the two jaw parts are connected to each other, preferably by means of a clamp spring; or are the two jaw parts independent with respect to each other, and they each comprise a complementary design connection mechanism that is designed for releasably coupling the two jaw parts to each other.

In this way the device offers increased ease of use, because the clamping spring ensures that the jaw parts automatically close in order to receive the main cable.

In one embodiment, the microcontroller is arranged to determine, assuming that the main cable exhibits a known clockwise field: - that a detected minimum amplitude indicates that an underlying main core is a neutral charger; - that phase 2 is located opposite the neutral charger; - that phase 1 has a phase lead compared to phase 2; and - that phase 3 is lagging behind phase 2.

In an alternative or additional embodiment, the microcontroller is arranged to determine, assuming that the main cable exhibits a known counterclockwise field: - that a detected minimum amplitude indicates that an underlying main core is a neutral charger; - that phase 2 is located opposite the neutral charger; - that phase 1 is lagging behind phase 2; and - that phase 3 has a phase lead compared to phase 2.

Note that this determination can be made assuming a known conventional dextrorotatory or counterclockwise electric field. In the event that the direction of rotation of the electric field is not known, it is possible to conveniently determine this in another way, as will be described below with reference to the use of another device.

In one embodiment, the device comprises an indicator, preferably a buzzer or an optical indicator, wherein the microcontroller is arranged to control the indicator so that the indicator gives an indication when the maximum amplitude or minimum amplitude is detected.

This allows to help the operator to rotate the device more smoothly to a suitable rotation angle.

In one embodiment, the microcontroller is designed to convert the measured voltage or voltages from a time domain to a frequency domain by means of a Fourier transform; wherein the microcontroller is arranged to determine the locations of the main cables, based on at least one frequency peak corresponding to the maximum amplitude or minimum amplitude when the device is rotated around the main cable.

In this way it is possible to exclude higher and lower frequencies than the mains voltage frequency, and the interpretation of maximum amplitude and minimum amplitude is easier, namely as a simple height of the peak around the mains voltage frequency in the frequency domain.

In one embodiment, the device comprises a gyroscope adapted to determine an angle of rotation made by the device with respect to a conventional vertical direction, preferably the direction of gravity, whereby the microcontroller is adapted to take into account when determining the locations of the main veins with the angle of rotation determined by the gyroscope.

This allows the microcontroller to determine the locations of the main wires independently of the current rotation angle of the device, because the microcontroller can compensate for the current rotation angle of the device.

In one embodiment, the device comprises at least one indication means, wherein the microcontroller is adapted to control the at least one indication means on the basis of the determined locations of the main veins, such that the at least one indication means gives an indication of an underlying main vein or respective underlying main veins. .

In this way there is increased ease of use, more accuracy, and better precision in the indication of the zone for the operator.

In a specific embodiment the at least one indication means comprises at least one of the following: an indication zone, preferably an LED strip; and a preferably cylindrical screen.

In an embodiment, where the at least one indication zone has a first, second, third and fourth indication zone, the microcontroller is designed to display the respective colors of the main wires, preferably by: - the first indication zone with a first color, preferably green, to indicate that an underlying main vein is a zero charge; - illuminate the second indication zone with a second color, preferably yellow, to indicate that the underlying main vein is phase 2, opposite the zero charge; and in the event that the main cable shows a clockwise field: - illuminate the third indication zone with a third color, preferably red, to indicate that the underlying main conductor is phase 1, with a phase lead compared to phase 2; and - illuminate the fourth indication zone with a fourth color, preferably blue, to indicate that the underlying main vein is phase 3, with a phase lag compared to phase 2; or in the event that the main cable shows a counterclockwise field: - illuminate the third indication zone with a third color, preferably red, to indicate that the underlying main conductor is phase 1, with a phase lag compared to phase 2; and - illuminate the fourth indication zone with a fourth color, preferably blue, to indicate that the underlying main vein is phase 3, with a phase advance compared to phase 2.

Alternatively or additionally, the device comprises a communication module, preferably a Bluetooth module, which is designed to communicate with a user device, preferably a smartphone, of an installer, and to indicate by means of that communication which main conductor is located where in the main cable.

In one embodiment, the device comprises a module for determining data relating to branches, such as data about a location, preferably a

GNSS, in particular GPS, module, and a communication module, with which the device can send the data to a central database. In this way, an operator can remain better informed of which branches are located where on the main cable or cables.

The present invention also provides for the use of a device according to one of the embodiments described above for determining the position and nature of main cores of a main cable.

In an embodiment of the use, because the use additionally: - connecting a housing branch sleeve comprising at least one contact pin; - inserting the at least one contact pin into respective main cores of the main cable by means of a mechanism, which mechanism is designed to insert each contact pin of the at least one contact pin into the main core under a guaranteed tension or with a guaranteed tightening torque or at a guaranteed depth to bring.

Such an automatic mechanism can, for example, operate by means of a pre-imposed spring tension of a spring that is automatically released, or by means of a pre-set motor, or by means of a pre-set pressure that can be built up by means of a pneumatic reservoir, or by means of a contact pin with a well-chosen shear bolt that is designed to break at a preset tension, or by means of a bolt with a fixed setting depth, etc.

The present invention also provides a device for determining the nature of main cores of a main cable, comprising: - an essentially annular bracket, at least on its inside, provided with a recess for receiving the main cable in a position of use; - at least one hollow pipe, extending radially away from an imaginary center of the recess, wherein the or each hollow pipe is provided with a sharp end directed towards the imaginary center of the recess, which sharp end is designed to cut plastic as soon as the cutting pressure reaches a threshold value exceeds; and - at least one plastic arrowhead, designed to be clamped in the condition of use between the or each sharp end and the main cable, with the tip of the or each plastic arrowhead pointed towards the imaginary center of the recess.

This device makes it possible to see the insulation color and therefore the nature of the main cores, in order to determine which main core it is.

The hollow pipe can be pressed through an outer sheath of the main cable and an outer sheath of the main core, and itself pushes aside the wires of the earth screen in the outer sheath thanks to the plastic arrowhead. Then the plastic arrowhead will hit the aluminum of the main core, which will increase the pressure to such an extent that the sharp end of the hollow pipe cuts through the plastic arrowhead, as well as through the (typically colored) insulation layer of the main core, leaving a particle of the insulation layer behind into the cavity of the hollow pipe and can thus be easily extracted if desired.

In one embodiment the bracket comprises at least two complementary parts, which parts are designed to be connected to each other in order to form the bracket in a dimensionally stable manner. Note that a “bracket” in this context refers to a “ring for closing an object” — the closure can be fixed, springy or hinged.

In this way the device can be used anywhere along the main cable.

In one embodiment, the device comprises at least one injection member designed to inject a filler, such as resin, into the main vein.

In this way the main vein can be made locally waterproof or at least more water-resistant. This can be used against local water intrusion, as well as against water intrusion by capillary action along the length of the main cable from water that has entered the main cable from more distant water contact points.

The present invention also provides for the use of a device for determining the nature of main cores of a main cable according to one of the embodiments described above.

The present invention also provides a system for determining the position and nature of main cores of a main cable, comprising a device for determining the position and nature of main cores of a main cable according to one of the embodiments described above and a device for determining a nature of main cores of a main cable according to one of the embodiments described above.

The present invention also provides for the use of such a system for determining the position and nature of main cores of a main cable, wherein the device for determining the nature of the main cores - i.e. the device comprising at least one hollow pipe - is used if it rotating field of the main cable is unknown in advance, whereby a particle of a colored insulation wall of at least one chosen main core can be cut and loosened from the main cable by means of at least one hollow pipe, so that the nature of the particle becomes visible through visual inspection of the particle. has at least one chosen main vein.

The present invention also provides a device for electrically connecting to at least one main core of main cores of a main cable, comprising: - an essentially annular bracket, at least on its inside, provided with a recess for receiving the main cable in a position of use;

- at least one electrically conductive contact pin, extending radially away from an imaginary center of the recess, wherein the or each contact pin is provided with a sharp end directed towards the imaginary center of the recess, which sharp end is adapted to cut plastic as soon as the cutting pressure exceeds a threshold value; and - at least one covering enclosing the at least one contact pin, formed from an electrically insulating material, preferably plastic, and provided with a pointed end directed towards the imaginary center of the recess, wherein the at least one covering is designed to fit into the in use, be pierced by the or each sharp end of the at least one contact pin, in particular at its or their pointed end.

In this way, the electrically conductive contact pin, encased in its sheath, can be pierced through an outer sheath of the main cable and an outer sheath of the main core thanks to sufficient pressure, whereby the wires of the earth screen in the outer sheath can also be pushed aside. The cutting pressure will then pierce its own sheathing, so that an electrical connection - electrically isolated from the rest of the environment thanks to the sheathing - can be established between the electrically conductive contact pin and the main core. Conduction with the main conductor can then be achieved via the contact pin.

This device can be referred to in this context as a house branch sleeve.

In one embodiment the bracket comprises at least two complementary parts, which parts are designed to be connected to each other in order to form the bracket in a dimensionally stable manner.

In one embodiment, the device comprises at least one injection member designed to inject a filler, such as resin, into the main vein.

The present invention also provides for the use of such a device for electrically connecting to at least one main core of main cores of a main cable.

Those skilled in the art will be able to understand the above-described embodiments of the present invention even more fully with the aid of the description that follows and the accompanying drawings, in which:

Figure 1 schematically shows an example of an embodiment of a device according to the present invention;

Figure 2 schematically shows another example of an embodiment of a device according to the present invention;

Figure 3 schematically shows yet another example of an embodiment of a device according to the present invention;

Figure 4 shows four graphs with an example of signals that can be detected or used by a device according to the present invention;

Figure 5 schematically shows an example of a hollow pipe that can form part of a device according to the present invention;

Figure schematically shows an example of an embodiment of a second device according to the present invention;

Figure 7 schematically shows an example of an embodiment of a third device according to the present invention; and

Figure 8 schematically shows an example of an application for a device according to the present invention.

Figure 1 schematically shows an example of an embodiment of a device according to the present invention. The device serves to determine the position and nature of main cores of a main cable 100, wherein the device is rotatable around the main cable 100 in a state of use. The device comprises at least one conductor 101A-C, which is electrically insulated from the main cores 106B, 106G , 106R, 106Y, preferably through existing insulation walls such as outer wall 105 and/or insulation wall 109 of the main cable. The or each conductor 101A-C is arranged to be located in the in-use condition at an outer wall 105 of the main cable 100, wherein the or each conductor 101A-C extends along a longitudinal direction that shares at least a longitudinal component with a longitudinal direction of the main cable 100 .

The device furthermore comprises a voltage meter 103 adapted to measure a voltage or voltages between the or each conductor 101A-C and a predetermined reference point 104, which voltage or voltages are generated by electrostatic influence of charge carriers in the main conductors 106Y, 106R, 106G, 106B (collectively referred to as 106) when the or each conductor 101A-C is in the in-use condition at the outer wall 105 of the main cable 100. To this end, the voltage meter 103 can be coupled 102 to the respective conductor or conductors 101A-C. In this example, one such coupling 102 is shown, but those skilled in the art will recognize that such couplings are possible with multiple conductors 101A-C. The device furthermore comprises a microcontroller (not shown) adapted to detect a maximum amplitude or minimum amplitude of the measured voltage or voltages when the device is rotated around the main cable 100 in the in-use condition, and adapted to determine the locations of the main wires 108 based on the detected maximum amplitude or minimum amplitude.

The figure also shows some auxiliary wires 107, in particular 107Y, 107R, 107G, 107B, which are less relevant to the device, as well as an earth screen 108.

The operation of the device will be more clearly described with reference to the embodiment of Figure 3, which can be seen as a further development of the embodiment of Figure 1.

Figure 2 schematically shows another example of an embodiment of a device 200 according to the present invention. The device 200 is shown abstractly in this figure, but may correspond in form to, for example, the embodiment of Figure 1 and/or Figure 3. The device 200, like the embodiment of Figure 1, comprises at least one conductor 201, coupled to a voltage meter 202, and a microcontroller 203. The voltage or voltages read by the voltage meter 202 can be presented to the microcontroller, which can determine the locations of the main wires on that basis, as explained above.

The device 200 may also include an optional buzzer 204, which functions as an indicator, wherein the microcontroller 203 is arranged to control the buzzer 204 so that it gives an indication when the maximum amplitude or minimum amplitude is detected. An alternative indicator can, for example, be an LED that emits maximum or minimum light respectively, or a clicker that indicates the amplitude with a click frequency, or any other useful indicator.

The device 200 may also comprise at least one optional indication means 205, wherein the microcontroller 203 is adapted to control the at least one indication means 205 on the basis of the determined locations of the main veins, such that the at least one indication means 205 gives an indication of an underlying main vein or respective underlying main veins. A useful indication means is, for example, an indication zone such as an LED strip, but a full-fledged display, preferably a cylindrical one so that it fits well with the shape of the main cable 100, can also be used. The LED strip can be controlled by the microcontroller 203 to indicate the nature of an underlying main wire by means of a well-chosen color. If the LED strip contains a sufficiently large number of separate LEDs, it is possible to determine the position with sufficient certainty and precision.

Figure 3 schematically shows yet another example of an embodiment of a device 300 according to the present invention, mounted on a main cable 100 as described with respect to Figure 1. The device may comprise an annular recess 302, adapted to receive the main cable 100. This recess 302 is essentially annular because it does not have to be closed around the main cable 100 in order to work properly (as is the case in the example shown here), although it may of course be closed all around. In this example, the device 300 comprises two complementary designed jaw parts 301A-B which, in use, form the recess for receiving the main cable 100.

It is advantageous to connect the jaw parts 301A-B to each other as in this example, for example by means of a clamping spring, with corresponding operating points 304A-B, in order to easily open and close the device 300 around a main cable 100.

The figure also shows the optional indicator, here a buzzer 308, as described in the context of Figure 2, and the optional indication zone, here an LED strip 303, also as described in the context of Figure 2. In addition, the device 300 can be shown as in this example, comprise a battery 305 to power other components of the device 300.

The figure also shows recesses 307 in the device for receiving the conductors, such that they are located in the vicinity of the outer wall 105 of the main cable 100 in the condition of use.

Figure 4 shows four graphs with an example of signals that can be detected or used by a device according to the present invention.

Graph 401 shows a voltage in mV measured over time, as observed by the voltmeter on one of the conductors of the device. In practice, this voltage can be noisy, as shown in graph 401. Nevertheless, it is possible to observe a dominant frequency 405 in the measured voltage, as shown in graph 402. An easy and surefire way to detect this dominant frequency 405 is shown in graph 403, where the measured voltage has been converted from the time domain to the frequency domain in Hz, by means of a

Fourier transform, where a peak 406 is clearly visible around 50 Hz, which indicates that alternating voltage has been applied to the main core above which the conductor is located at the mains frequency 50 Hz. By rotating the device, it becomes possible to detect when this peak 406 reaches a maximum 408 or a minimum 407 in amplitude, as shown in graph 404. By comparing these extrema with each other, it is possible to determine the nature of to determine the underlying main conductor, as indicated in graph 404 with the references 1, 2, 3, Zero, for the different phases and the zero charger. It is advantageous if the device also comprises a gyroscope that is designed to determine an angle of rotation made by the device relative to a conventional vertical direction, preferably the direction of gravity, wherein the microcontroller is designed to determine the locations of the main veins take into account the angle of rotation determined by the gyroscope. In this way it can be accurately determined at which rotation angle maximum 408 and/or minimum 407 occur.

Figure 5 schematically shows an example of a hollow pipe 501 that can form part of a device according to the present invention. The hollow pipe 501 is provided with a sharp end 502 that is designed to cut plastic as soon as the cutting pressure exerted on the sharp end 502 exceeds a threshold value. The figure also shows a plastic arrowhead 503 which will be described below. Hollow pipe 501 will be further illustrated with reference to Figures

Gene".

Figure 6 schematically shows an example of an embodiment of a second device 600 according to the present invention, seen in perspective. The device 800 serves to determine the nature of main cores of a main cable, such as main cable 100 shown in Figure 1. The device 600 comprises an essentially annular bracket 601, at least on its inside, provided with a recess 602 for receiving cables in a position of use. the main cable 100. The device 600 also comprises at least one hollow pipe 603, such as for example hollow pipe 501 of Figure 5, extending radially away from an imaginary center of the recess 602, wherein the or each hollow pipe 603 is provided with a sharp end 502 directed towards the imaginary center of the recess 602, which sharp end 502 is designed to cut plastic as soon as the cutting pressure exceeds a threshold value. The device 600 also comprises at least one plastic arrowhead 503, designed to be clamped in the position of use between the or each sharp end 502 and the main cable, with the tip of the or each plastic arrowhead 503 directed towards the imaginary center of the recess 602.

Figure 7 schematically shows an example of an embodiment of a third device 700 according to the present invention, seen in cross-section. The device 700 serves for electrically connecting to at least one main core of main cores of a main cable, such as main cable 100 shown in Figure 1. The device 700 comprises an essentially annular bracket 701, at least on its inside, provided with a recess 702 for mounting in a position of use. receiving the main cable 100. The device 700 additionally comprises at least one electrically conductive contact pin 703, extending radially away from an imaginary center of the recess 702, the or each contact pin 703 being provided with a sharp end directed towards the imaginary center of the recess 702, which sharp end is designed to cut plastic as soon as the cutting pressure exceeds a threshold value. The device 700 also comprises at least one covering through which the at least one contact pin 703 is covered, formed from an electrically insulating material, preferably plastic, and provided with a pointed end directed towards the imaginary center of the recess 702, wherein the at least one covering is designed to be pierced in the state of use by the or each sharp end of the at least one contact pin 703, in particular at its or their pointed end.

Each contact pin 703 is housed in a preferably plastic covering, which covering serves to electrically insulate the contact pins 703 from the earth screen.

The sheath also has a pointed end to penetrate the main cable 100 up to the main cores 106B-G-R-Y. The contact pin 703, upon penetrating the main core 106B-G-R-Y, will split the plastic sheath once the pressure applied to it exceeds a certain threshold value, and will then further penetrate the main core 106B-G-R-Y and make electrical contact with this main core 106B-G-R-Y.

Figure 8 schematically shows an example of an application for a device according to the present invention. In an example situation, a house 805 (or other type of building) must be connected to a main cable 801-802, using a house branch sleeve. In such situations it is not always clear from which main cable to branch off, for example if there are several main cables present.

In that case, a commonly used solution is to place a current train from a central 803, for example from a transformer house, on two main cores in the main cable 801 — one main core carries the current train in one direction, the other main core in the other — so that an installer with a known clamp meter or simple coil can determine which main cable is the correct one. This is because the clamp meter will show the current train running on the two main wires of the correct main cable, and will show no identifiable result (e.g. just noise) when the clamp meter is connected to the wrong main cable.

However, a common problem is that a house 805 (or other type of building) needs to be connected to an end 802 of the main cable that is beyond the last termination 804 of the main cable circuit as viewed from the exchange. In that case it is impossible to detect such a current train with the known clamp meter or coil, since the main cable does not form a closed circuit in that end 802 of the main cable.

The device according to the present invention solves this problem because it is able to detect the voltage train induced by such a current train, even in that end 802 of the main cable, because voltage can be detected on the main cores, even if the circuit is not closed.

Claims (4)

CONCLUSIONS 1. Device for electrically connecting to at least one main core of main cores of a main cable, comprising: - an essentially annular bracket, at least on its inside, provided with a recess for receiving the main cable in a position of use; - at least one electrically conductive contact pin, extending radially away from an imaginary center of the recess, wherein the or each contact pin is provided with a sharp end directed towards the imaginary center of the recess, which sharp end is adapted to cut plastic as soon as the cutting pressure exceeds a threshold value; and - at least one covering enclosing the at least one contact pin, formed from an electrically insulating material, preferably plastic, and provided with a pointed end directed towards the imaginary center of the recess, wherein the at least one covering is designed to fit into the in use, be pierced by the or each sharp end of the at least one contact pin, in particular at its or their pointed end. 2. Device according to claim 1, wherein the bracket comprises at least two complementary parts, which parts are designed to be connected to each other in order to form the bracket in a dimensionally stable manner. Device according to claim 1 or 2, comprising at least one injection member designed to inject a filler, such as resin, into the main vein. 4. The use of a device according to any one of claims 1-3 for electrically connecting to at least one main core of main cores of a main cable.