DE102019127148B4 - Power supply component and system for power supply with the same - Google Patents

Abstract

Power supply component (4) for the power supply of one or more consumers (34), which can be connected to different power sources, having: at least one first electrically conductive element (8) which has the ground potential in the operating state, and at least two second electrically conductive elements (10- 1, 10-2), each having a conductor track (12-1; 14-2) and an electrically insulating carrier material (16), the conductor tracks (12-1, 14-2) having different voltages in the operating state, and are each accommodated in the respective electrically insulating carrier material (16) in such a way that the conductor tracks (12-1, 14-2) each protrude at least from an upper side (50) of the carrier material (16), the at least one first electrically conductive element (8) is block-like and has recessed grooves (46, 48) extending along a direction and in a direction perpendicular to the direction of extension par are arranged allel to each other, wherein first of the recessed grooves (46) have a first depth and second of the recessed grooves (48) have a second depth different from the first depth, wherein the first and second recessed grooves (46, 48) are arranged alternately and in the first of the at least two second electrically conductive elements (10-1) are arranged in the first recessed grooves (46) and second of the at least two second electrically conductive elements (10-2) are arranged in the second recessed grooves (48).

Description

The invention relates to a power supply component for supplying power to one or more consumers, which can be connected to one or more different power sources, e.g. an AC power source, a DC power source, a signal power source, a mixed power source, etc., and a system for power supply to one or more consumers , With a power supply component according to the invention and at least one current collector component for supplying a consumer, which can be coupled to the power supply component.

The majority of all electrical consumers in the household, such as lighting, televisions, vacuum cleaners or drills, are low-voltage devices, i.e. they get by with a voltage of between around 5 V and around 12 V. In order for low-voltage devices to be used, the voltage must first be reduced from the usual standard voltage, usually around 220 V, to the appropriate low voltage. Mains units are usually used for this, and in most cases these are individually adapted to the low-voltage consumer.

Due to the increasing number of low-voltage devices, the problem arises that the number of low-voltage devices to be connected exceeds the number of limited power sources, in particular sockets, that are available. Remedies such as multiple plugs and/or extension cords are only unsatisfactory and shift the problem to another place, but do not solve it. In the worst case, these even represent a potential hazard.

US 2016/ 344 135 A1 discloses a modular shelving system comprising at least one shelf module, a power module connected to the at least one shelf module, and a conductor assembly connected to the at least one shelf module and electrically connected to the power module. The conductor assembly includes a circuit board having a first row of openings and a second row of openings, a backplate formed from a ferromagnetic material or a magnetic material, a first conductor electrically coupled to the power module, and between the backplate and of the board and a second conductor electrically connected to the power module and positioned between the backplate and the board. The first conductor aligns with the first row of holes in the circuit board. The second conductor aligns with the second row of openings on the circuit board.

According to JP 2009 - 087 676 A A mounting device for electrical equipment includes a mounting plate provided with a first electrode plate laminated on one surface of a base plate, a second electrode plate laminated on the other surface of the base plate, mounting holes formed in multiple locations in the second electrode plate and the base plate, and a connector which is provided with an electric equipment mounting portion which is arranged on the same side as the second electrode plate on the mounting board and to which an electric device is attached. The mounting device also includes one or more pins which are arranged on the attachment portion of the electrical device and which can be inserted into and removed from the attachment holes, a magnet which is arranged on the attachment portion of the electrical device and attaches the attachment portion by magnetic force to the other electrode plate pulls. A first power supply portion is disposed on the pin portion and is electrically connected to the electrode plate. A second power supply portion is disposed on the electrical equipment connection portion and electrically connected to the other electrode plate.

US 2010 / 317 233 A1 describes a connection structure between electronic modules each having a plurality of terminals and a plurality of electrodes, and an electrical connection system between electrical modules in which terminals and electrodes included in electronic modules can be easily electrically connected. In the electrical connection system between a fixed module and a moving module, the fixed module includes a cradle surface on which a concave-convex surface including a plurality of convex surfaces and a plurality of concave surfaces are arranged. A commonly connected terminal having a first pole is formed on the convex surfaces and a commonly connected terminal having a second pole is formed on the plurality of concave surfaces. The moving module includes a contact surface that mates with the cradle surface of the fixed module. The contact surface includes a planar portion and at least one portion protruding from the planar portion. A first load electrode, which is a conductive element connected to a first pole of a movable module load included in the moving module, is formed on at least a part of a surface of the planar portion. A second load electrode, which is a conductive member connected to a second pole of the movable module load, is formed in an end portion of the protruding portion. The first las t electrode and the second load electrode are insulated from each other. The end portion of the protruding portion is received in one of the plurality of concave surfaces of the fixed module so that the first load electrode is connected to the first pole of the fixed module and the second load electrode is connected to the second pole of the fixed module.

DE 10 2017 005 348 A1 discloses a modular lighting system with a carrier module and at least one lighting module. The carrier module has at least one recess for accommodating an illumination module. In the area of \u200b\u200bthe recesses there are magnetic adhesion and contacts for power supply. The lighting module is guided in a recess of the carrier module at least in two edge regions. The lighting module is attached to the carrier module by magnetic adhesion. An energy connection is created through contact points.

EP 1 733 653 A2 describes a lighting device for showcases or showrooms with at least one base to which the conductors are fixed in one piece and at least one lamp holder body in which the light sources are arranged. The lamp holder has permanent magnets attached thereto which are arranged for mutual engagement opposite conductive rods.

a in DE 10 2008 024 776 A1 The light source described has one or more individual light sources with an electrical connection that adheres magnetically, in particular with two electrical connections that adhere magnetically. The electrical connection is a permanent magnet and includes a laminar contact. One of the light sources includes a light emitting diode. A carrier includes two sets of electrical contacts, and a lighting system includes an illuminant and a carrier.

DE 1 936 568 U discloses an electrical connector for connecting electronic circuits or components to first and second groups of signal conductors disposed on opposite sides of a support plate of insulating material such that each conductor of a first group overlies conductors of the second group, with connecting conductors for connecting predetermined conductors of the first and second groups, to shielding conductors shielding the signal conductors in the manner of a coaxial cable, and to a first group of grooves on one side of the support plate and a second group of grooves on the opposite side of the support plate. The signal and shield conductors are formed as electrically conductive coatings, each continuous, on the walls of the grooves, and the shield conductors are interconnected through apertures provided with conductive coatings. Each group of grooves alternates between deep grooves and shallow grooves. The deep groove coatings are the shield conductors and the shallow groove coatings are the signal conductors. The depth of the deep grooves is such that there are openings in the support plate at the intersections of the deep grooves of one set with the deep grooves of the other set, and the sum of the depths of the shallow grooves of one set and the deep grooves of the other set group is less than the thickness of the mounting plate, as is the sum of the deep grooves of one group and the shallow grooves of the other group.

According to EP 0 828 323 A2 a rail system comprises a carrier profile with a channel-shaped chamber system for accommodating a number of conductor rails for connecting a number of electrical instruments. The carrier profile is preferably formed from a first, load-bearing and conductive profile part and a second, insulating profile part arranged therein.

DE 10 2017 125 263 A1 discloses a conductor rail arrangement with a metal trough extending in a longitudinal direction and with current-carrying profiles also extending in the longitudinal direction. The current-carrying profiles have a plurality of grooves which extend parallel to one another in the longitudinal direction and are delimited laterally by webs and at the bottom of the groove by a base connecting the webs. Electrical conductors are accommodated in the slots. The current-carrying profiles are installed in the metal trough. The current-carrying profiles are connected to the metal trough in a central area by positive locking and are movable in the direction of longitudinal extension relative to the metal trough at their end areas adjoining the central area.

The object of the invention is therefore to provide a power supply component and a system for power supply with a power supply component that make it possible to provide different low voltages directly and preferably for multiple loads that can have different voltages at the same time on the power supply component.

The object of the invention is achieved by a power supply component according to independent patent claim 1 and a power supply system according to independent patent claim 4 . Advantageous further education result from the dependent patent claims.

A power supply component according to the invention for supplying power to one or more loads that can be connected to different power sources has at least a first electrically conductive element which has ground potential in the operating state; and at least two second electrically conductive elements, which each have a conductor track and an electrically insulating carrier material. In the operating state, the conductor tracks have different voltages from one another and are each accommodated in the respective electrically insulating carrier material in such a way that the conductor tracks each protrude at least from an upper side of the carrier material. The at least one first electrically conductive element is designed in the form of a block and has indentation grooves which extend along one direction and are arranged parallel to one another in a direction perpendicular to the direction of extension. First of the deepening grooves have a first depth and second of the deepening grooves have a second depth different from the first depth, the first and second deepening grooves being arranged alternately and first of the at least two second electrically conductive elements being arranged in the first deepening grooves and in the second deepening grooves second of the at least two second electrically conductive elements are arranged.

A possible embodiment of the power supply component provides that the at least one first electrically conductive element also has third depression grooves with a third depth and a third, second electrically conductive element, which has a conductor track and an electrically insulating carrier material. The conductor track of the third, second electrical element has a voltage that differs from the other voltages during operation and is accommodated in the electrically insulating carrier material of the third, second electrical element in such a way that the conductor track at least protrudes from an upper side of the carrier material. The more interconnects of different voltages are provided, the more different voltages, which can also result from the combinations of the voltages of the interconnects, can be provided by the power supply component.

It has proven to be advantageous if the at least one first electrically conductive element has a soft-magnetic material. This allows any magnet to adhere to the first electrically conductive member.

A current collector component for supplying a consumer has an electrically conductive ground contact element, which is prepared for contacting the at least one first electrically conductive element of the power supply component according to the invention, at least one electrically conductive conductor track contact element, which is prepared for contacting a conductor track of the power supply component, and a carrier element, formed of an electrically insulating material. The carrier element has an underside that is prepared for contacting the power supply component, and the ground contact element is accommodated in the carrier element in such a way that it is arranged flush with the underside. The at least one electrically conductive conductor track contact element has an electrically conductive contact pin, on the lateral surface of which electrical insulation is arranged, and the at least one electrically conductive conductor track contact element is accommodated in the carrier element in such a way that it protrudes from the underside of the carrier element in such a way that between the conductor track contact element and a contact can be formed on a conductor track of the power supply component.

An advantageous embodiment of the current collector component provides that it also has a second electrically conductive conductor track contact element, which is prepared for contacting a conductor track of the power supply component, the second electrically conductive conductor track contact element having an electrically conductive contact pin, on the lateral surface of which electrical insulation is arranged, and the second electrically conductive conductor track contact element is accommodated in the carrier element in such a way that it protrudes from the underside of the carrier element in such a way that a contact can be formed between the second electrically conductive conductor track contact element and a conductor track of the power supply component. The two conductor track contact elements are preferably connected to one another in an electrically conductive manner in order to combine, in particular to cumulate, the two identical voltages with one another.

As with the current collector components described above, it has also been shown to be advantageous for the current collector component if at least one magnet is also accommodated in the carrier element. The current collector component can, for example, adhere to the power supply component by means of the magnet.

A system according to the invention for supplying power to one or more loads has a power supply component according to the invention and at least one current consumer component. This includes the pantograph component: an electrically conductive ground contact element that is prepared for contacting a first electrically conductive element of the power supply component, at least one electrically conductive conductor track contact element that is prepared for contacting a conductor track of the power supply component, and a carrier element that is made of an electrically insulating material. The carrier element has an underside that is prepared for contacting the power supply component, and the ground contact element is accommodated in the carrier element in such a way that it is arranged flush with the underside. The conductor track contact element has an electrically conductive contact pin, on the outer surface of which electrical insulation is arranged. The conductor track contact element is accommodated in the carrier element in such a way that it protrudes from the underside of the carrier element in such a way that a contact can be formed between the conductor track contact element and a conductor track of the power supply component.

In addition, it is also conceivable to combine the so-called form-fitting plug-in connections with magnetic connections, with the matching geometric components of the power supply component and the current collector component each having magnets that attract one another.

• 1(a) eine schematische Darstellung eines Systems zur Stromversorgung mit einer Stromversorgungskomponente und Stromabnehmerkomponenten, das nicht Bestandteil der beanspruchten Erfindung ist;
• 1(b) schematische Darstellungen zweier möglicher Stromabnehmerkomponenten des in der 1 (a) gezeigten Systems je in einer Draufsicht sowie einer seitlichen Ansicht;
• 2(a) eine schematische Darstellung des Systems zur Stromversorgung mit einer Stromversorgungskomponente und einer Stromabnehmerkomponente, das nicht Bestandteil der beanspruchten Erfindung ist;
• 2(b) schematische Darstellungen zweier möglicher Stromabnehmerkomponenten des in der 2(a) gezeigten Systems je in einer Draufsicht sowie einer seitlichen Ansicht;
• 3 eine schematische Darstellung eines erfindungsgemäßen Systems zur Stromversorgung mit einer erfindungsgemäßen Stromversorgungskomponente und mehreren Stromabnehmerkomponenten
• 4 eine Draufsicht auf ein elektrisch isolierendes Trägermaterial;
• 5 eine schematische Darstellung eines erfindungsgemäßen Systems zur Stromversorgung in einer perspektivischen Ansicht;
• 6A einen Ausschnitt einer schematischen Schnittansicht des erfindungsgemäßen Systems;
• 6B-D verschiedene Anordnungen des erfindungsgemäßen Systems;
• 7 eine schematische Draufsicht des erfindungsgemäßen Systems;
• 8(a) eine schematische Darstellung einer möglichen konstruktiven Ausführung einer Überstromschutzvorrichtung;
• 8(b) die Überstromschutzvorrichtung aus 8(a), wobei die Überstromschutzvorrichtung als elektrischer Schaltkreis dargestellt ist;
• 9 eine weitere Ausführungsform der Stromversorgungskomponente, wobei die verschiedenen Spannungen separat gezeigt sind; und
• 10 zeigen die Ausführungsform der Stromversorgungskomponente aus 9 in überlagerter Darstellung.

The invention is explained in more detail below with reference to the accompanying drawings. Show it:

• 1(a) a schematic representation of a system for power supply with a power supply component and current collector components, which is not part of the claimed invention;
• 1(b) schematic representations of two possible pantograph components in the 1 (a) system shown in a top view and a side view;
• 2(a) a schematic representation of the system for power supply with a power supply component and a current collector component, which is not part of the claimed invention;
• 2 B) schematic representations of two possible pantograph components in the 2(a) system shown in a top view and a side view;
• 3 a schematic representation of a power supply system according to the invention with a power supply component according to the invention and a plurality of current collector components
• 4 a plan view of an electrically insulating carrier material;
• 5 a schematic representation of an inventive system for power supply in a perspective view;
• 6A a detail of a schematic sectional view of the system according to the invention;
• 6B-D various arrangements of the system according to the invention;
• 7 a schematic plan view of the system according to the invention;
• 8(a) a schematic representation of a possible structural design of an overcurrent protection device;
• 8(b) the overcurrent protection device off 8(a) , wherein the overcurrent protection device is shown as an electrical circuit;
• 9 another embodiment of the power supply component with the different voltages shown separately; and
• 10 show the embodiment of the power supply component 9 in superimposed representation.

The figures are only of a schematic nature and serve only to understand the invention. The same elements are provided with the same reference numbers.

Features of the individual exemplary embodiments can also be implemented in other exemplary embodiments. So they are interchangeable.

1(a) shows a first exemplary embodiment of a first power supply system 2, which is not part of the claimed invention, with a power supply component 4 and a plurality of current collector components 6 in a schematic representation.

The power supply component 4 can be connected to at least one conventional power source and has a first electrically conductive element 8 and a second electrically conductive element 10. The first electrically conductive element 8, which is simply referred to below as the first element 8, also corresponds to the negative pole called the negative pole of the electrical circuit and serves as a so-called ground contact, i.e. the first element 8 has the ground potential of 0 V in the operating state.

The second electrically conductive element 10, which is simplified below as the second Ele ment 10 corresponds to the positive pole, also known as the positive pole, of the circuit and, in the exemplary embodiment shown here, has two conductor tracks 12, 14 and an electrically insulating carrier material 16.

The two conductor tracks 12, 14 are embedded in the electrically insulating carrier material 16, which is referred to below simply as carrier material 16, and have different voltages in the operating state. The conductor track 12 has 5V here, for example, and the conductor track 14 has 12V, for example. Of course, other voltages are also conceivable. The conductor tracks 12, 14 are accommodated next to one another and at a distance from one another, preferably parallel to one another, in the carrier material 16.

Embodiments are also conceivable in which the first element 8, ie the ground contact, serves as a positive pole and has the ground potential or reference potential of 0 V in the operating state. The second element 10 then serves accordingly as a negative pole and the voltages of the conductor tracks 12, 14 are negative, ie, for example -5V and -12V.

The carrier material 16 has on its upper side 17 recesses 18, 20 which are designed in such a way that they expose the conductor tracks 12, 14 in sections. The first cutouts 18 are arranged along the conductor track 12 and have an outer contour that differs from an outer contour of the second cutouts 20 that are arranged along the conductor track 14 . The first recesses 18 are designed here as a four-pointed star, whereas the second recesses 20 are designed as a six-pointed star.

The first element 8 and the second element 10 are arranged next to each other in one plane, so that the first element 8 is in contact with the carrier material 16 of the second element 10 and the top side 17 of the second element 10 and a top side 22 of the first element 8 in lie in one plane and thus form a flat, planar surface.

In the exemplary embodiment shown here, three second elements 10 and four first elements 8 are shown, which are arranged alternately in one plane. The first element 8 is designed like a strip and extends parallel to the conductor tracks 12, 14 adjacent to at least one second element 10. Furthermore, all the strip-like first elements 8 are connected to one another via a connecting element 24, which extends essentially transversely to the conductor tracks 12, 14 extends.

On the top of the power supply component 4 three current collector components 6 are arranged, which are also referred to below 1(b) be described in more detail.

The current collector components 6 each have an electrically conductive ground contact element 26 and an electrically conductive conductor track contact element 28 which are accommodated in an electrically insulating carrier element 30 . The carrier element 30 has an underside 32 (see FIG 1 (b) ), which is in contact with the top of the power supply component 4 in the operating state.

As in 1(b) As can be seen, the ground contact element 26 is accommodated in the carrier element 30 in such a way that it is arranged flush with the underside 32 , while the conductor track contact element 28 protrudes from the underside 32 . The conductor track contact element 28 has a shape which corresponds to the outer contour of one of the cutouts 18, 20, so that when the conductor track contact element 28 is inserted into the corresponding cutout 18, 20 of the same contour, there is slight play.

In 1(b) two current collector components 6 are shown, the first of which has a conductor track contact element 28 with a four-pointed star shape, which corresponds to the outer contour of recess 18, and the second has a conductor track contact element 28 with a six-pointed star shape and thus corresponds to the outer contour of recess 20.

A consumer 34 is electrically conductively connected to the current collector component 6 , so that the consumer is supplied with electricity at the appropriate voltage when the power supply component 4 and the current collector component 6 are correctly coupled.

For this, the consumer is 34, as in 1(b) simplified and shown schematically, electrically conductively connected to both the ground contact element 26 and the conductor track contact element 28 .

Referring back to 1 (a) a first current collector component 6 with a connected consumer 34 is arranged on the power supply component 4 in such a way that the ground contact element 26 is in electrically conductive contact with the first element 8 and the six-pronged conductor track contact element 28 is inserted in a recess 20 so that the conductor track contact element 28 is connected to the conductor track 14 is in electrically conductive contact and the consumer 34 is supplied with electricity.

A second current collector component 6 with a connected consumer 34 is on the Power supply component 4 is arranged such that the ground contact element 26 is in electrically conductive contact with the first element 8 and the four-pronged conductor track contact element 28 is inserted into a recess 18, so that the conductor track contact element 28 is in electrically conductive contact with the conductor track 12 and the load 34 is supplied with power will.

A third current collector component 6 with a connected consumer 34 is arranged on the power supply component 4 in such a way that the six-pronged conductor track contact element 28 is inserted into a recess 20 so that the conductor track contact element 28 is in electrically conductive contact with the conductor track 14 . The ground contact element 26 is arranged on the second element 10 instead of on the first element 8, and is therefore in electrically non-conductive contact with the second element 10, as a result of which the load 34 is not supplied with current (represented by the hatched load 34). .

Due to the distance between the ground contact element 26 and the conductor track contact element 28 in the current collector component 6, a predetermined orientation of the current collector component 6 relative to the power supply component 4 must also be observed.

The different shapes of the recesses 18, 20 and the resulting different shapes of the conductor track contact elements 28 prevent a consumer from being accidentally connected to the wrong voltage and possibly being damaged as a result (e.g. due to excessive voltage).

2(a) and 2 B) Figure 12 shows a second system 2 not forming part of the claimed invention with the power supply component 4 and a plurality of current collector components 6 in top and side views. The second system 2 essentially corresponds to the first system, which is why only the differences from the first system are discussed below in order to avoid unnecessary repetition.

This in 2(a) The second system 2 of the power supply component 4 shown differs from that in 1(a) The first system 2 shown is that the first electrically conductive element 8 is designed in a planar or layered manner and is arranged on the upper side 17 of the second electrically conductive element 10 and has through holes 36, 38, which are congruent in position and shape with the recesses 18, 20 , which in the second element 10 expose the conductor tracks 12, 14 in sections are formed. In the exemplary embodiment shown here, as in the first exemplary embodiment, three second elements 10 (not visible) are provided, each of which is covered by a first element 8, these three pairs of first and second elements 8, 10 being arranged next to one another in such a way that they touch sideways.

The second system 2 of the pantograph component 6 is in particular with reference to 2 B) explained in more detail. 2 B) shows two current collector components 6, which differ in the shape of their conductor track contact element 28.

As in the first exemplary embodiment, the current collector component 6 has a ground contact element 26, a conductor track contact element 28 and a carrier element 30, with the ground contact element 26 and the conductor track contact element 28 being accommodated in the carrier element 30 at the best possible spacing from one another.

The ground contact element 26 is accommodated in the carrier element 30 in such a way that it is arranged flush with the underside 32 of the carrier element 30 . The conductor track contact element 28 protrudes from the underside 32 of the carrier element 30 .

In contrast to the first system 2, the conductor track contact element 28 of the second system 2 has an electrically conductive contact pin 40 on the outer surface of which electrical insulation 42 is arranged. The contact pin 40 is completely surrounded by the insulation 42 along its lateral surface. The conductor track contact element 28 is shaped in such a way that a form fit can be formed between the conductor track contact element 28 and either the first cutout 18 or the second cutout 20 . This means that the conductor track contact element 28 is designed either like a four-pointed star or like a six-pointed star, as in the first exemplary embodiment. Here, too, there is a small amount of play between the recess 18, 20 and the conductor track contact element 28 when the positive connection is formed.

The contact pin 40 protrudes from an underside 44 of the insulation 42, so that when the conductor track contact element 28 is inserted in a form-fitting manner into the correspondingly shaped recess 18 or 20, there is an electrically conductive contact between the contact pin 40 and the corresponding conductor track 12 or 14 comes. The insulation 42 prevents the contact pin 40 from coming into contact with the first element 8 when it is inserted into the corresponding recess 18 or 20, which would cause a short circuit and damage the current collector component.

As already in 1(a) are in 2(a) three current collector components 6 are arranged on the power supply component 4, so that a first current collector component 6, which has a six-pronged conductor track contact element 28, is electrically conductively connected to the power supply component 4 and supplies a consumer 34 with electricity. For this purpose, the conductor track contact element 28 is inserted into a recess 20 in a form-fitting manner such that there is an electrically conductive contact between the contact pin 40 and the conductor track 14, and the ground contact element 26 is in electrically conductive contact with the first element 8 of the power supply component. A second current collector component 6, which is also a six-pronged conductor track contact element 28, is analogous to 1(a) arranged with the ground contact element 26 on a recess 18, which is why no closed circuit comes about and the consumer 34 connected to this current collector component 6 is therefore not supplied with electricity. The third current collector component 6 has a four-pronged conductor track contact element 28 and is inserted through one of the first through-holes 36 into the first cutout 18 arranged underneath in a form-fitting manner, so that the contact pin 40 of the conductor track contact element 28 is in electrically conductive contact with the conductor track 12. The ground contact element 26 of this current collector component 6 is in electrically conductive contact with the first element 8 of the power supply component 4, so that the load 34 connected to this current collector component 6 is also supplied with current.

The first elements 8 can be designed, for example, as thin foils or plates with electrically conductive material. The electrically insulating carrier material 16 can be designed as a thin foil or plate with electrically insulating material.

3 shows a further schematic representation of a system 2 for power supply with a power supply component 4 and a current collector component 6, which is not part of the claimed invention. 3 differs from the 1(a) only by one of the current collector components 6, which is described in more detail below.

The current collector component 6 'has two six-pronged printed conductor contact elements 28, both of which are received in the carrier element 30 in such a way that they protrude from the underside 32 of the carrier element 30 and are arranged in such a way that they are in contact with two different second elements 10 of the power supply component 4 . Such an arrangement requires a larger support element 30, the ground contact element 30 is in 3 arranged between the two conductor track contact elements 28, for example, such that when the current collector component 6 is correctly brought into contact with the power supply component 4, i.e. when the conductor track contact elements 28 are inserted in a form-fitting manner into the recess 18 of the respective second element 10, with a first element 8 the power supply component is in contact.

The two conductor track contact elements 28 are electrically conductively connected to one another and a load 34 is electrically conductively connected to one of the two conductor track contact elements 28 and to the ground contact element 30 .

Such a current collector component 6 makes it possible to vary the amperage while the voltage remains the same. More precisely, this current collector component 6 allows the addition of the currents of the two lines, in this case the two 12V voltage lines (conductor 14). This makes it possible to increase the number of devices that can be supplied with electricity via this system.

In another embodiment, not shown here, it is also conceivable to provide a second conductor contact element 28 instead of the ground contact element 30 , which differs from the first conductor contact element 28 . For the exemplary embodiment shown here, this means that the current collector component 6 has a six-pronged conductor track contact element 28 and a four-pronged conductor track contact element 28 . With such a current collector component 6 it is possible to be able to provide other voltages that differ from the voltages of the conductor tracks. When the two conductor track contact elements 28 come into contact with the correct conductor tracks, i.e. here, the four-pronged conductor track contact element 28 comes with the conductor track 12, which has an SV voltage in the operating state, and the six-pronged conductor track contact element 28 comes with the conductor track 14, which in the Operating state has a 12V voltage in contact, the consumer connected to the pantograph component 6 is supplied with the differential voltage, ie, in the embodiment shown here with a 7V voltage. It is thus possible, through appropriate combinations, to also make the required voltage available to consumers who require voltages which differ from the voltages which the provided conductor tracks 12, 14 have in the operating state. It is important here that in such a case no additional ground contact element 30 is provided, since this would lead to a short circuit. With view on 1 and 2 should to the At this point it should be pointed out again that the examples of the ground contact element 30, which is arranged on one of the recesses 18, 20, therefore do not represent a closed circuit, because the ground contact element 30 is designed in such a way that, due to its geometry, it does not get into the recess 18, 20 fits in and therefore does not come into contact with the conductor track 12 or 14.

4 shows a plan view of the electrically insulating carrier material 16, as is particularly the case in the second system 2 (see 2a) ) is used. The arrangement of the first elements 8 and the second elements 10 of the power supply component 4 one above the other makes it possible to form the second elements 10 arranged next to one another integrally, ie in one piece. The same applies to the first elements 8.

the 5 until 7 show an embodiment of a system 2 according to the invention for powering one or more loads, wherein 5 shows a schematic representation of the system 2 in a perspective view; 6A depicts a detail of a schematic sectional view of the system 2, ie the power supply component 4 and the current collector component 6; and 7 shows a schematic top view of the system 2 .

The system 2 according to the invention has a first electrically conductive element 8 which is designed essentially in the form of a block and has indentation grooves 46 , 48 . The recessed grooves 46, 48 extend along a direction y and are arranged parallel to each other in a direction x. The recessed grooves 46 have a first depth t1 and the recessed grooves 48 have a second depth t2, the first depth t1 being smaller than the second depth t2. In other conceivable embodiments, the first depth t1 can also be greater than the second depth t2. The depression grooves 46, 48 are arranged alternately along the x-direction. The first element 8 has the ground potential (0 V) in the operating state.

Furthermore, the system 2 has two second electrically conductive elements 10 - 1 , 10 - 2 , the second elements 10 - 1 being arranged in the first recessed grooves 46 and the second elements 10 - 2 being arranged in the second recessed grooves 48 . The second elements 10-1, 10-2 have an electrically conductive strip conductor 12-1 or 14-2 and an electrically insulating carrier material 16-1, 16-2. One conductor track 12-1 has a first voltage, for example 5V, in the operating state, and the other conductor track 14-2 has a second voltage, which is different from the first voltage, for example 12V, in the operating state. The respective conductor track 12-1, 14-2 is accommodated in the corresponding carrier material 16-1, 16-2 in such a way that it protrudes from an upper side 50-1, 50-2 of the carrier material 16-1, 16-2.

Regarding 6A the current collector component 6 of the exemplary embodiment according to the invention is explained in more detail. The current collector component 6 has at least one electrically conductive ground contact element 26, in this case two electrically conductive ground contact elements 26, an electrically conductive conductor track contact element 28 and an electrically insulating support element 30, with the current collector component 6 also being able to have a plurality of conductor track contact elements 28-1, 28-2 in other embodiments .

The carrier element 30 has an underside 32 which rests on an upper side 52 of the first element 8 in the operating state. Both the ground contact elements 26 and the conductor track contact element 28 are accommodated in the carrier element 30 , the ground contact elements 26 being arranged flush with the underside 32 and the conductor track contact element 28 protruding from the underside 32 .

The conductor track contact element 28 has an electrically conductive contact pin 40 which is surrounded by an electrical insulation 42 along its lateral surface. The conductor track contact element 28 protrudes from the underside 32 of the carrier element 30 such that when the underside 32 of the carrier material 30 is brought into contact with the upper side 52 of the first element 8, the contact pin 40 comes into contact with the conductor track 14-2. The consumer 34 is electrically conductively connected to one of the ground contact elements 26 and to the conductor track contact element 28 .

In addition, the ground contact elements 26 and the conductor track contact element 28 are arranged in the carrier element 30 in such a way that they do not touch one another. The current collector component 6 is designed such that when it comes into contact with the power supply component 4, the ground contact elements 26 touch the upper side 52 of the first element 8 and the conductor track contact element 28 is inserted or introduced into the recessed groove 48. For this purpose, the contact pin 40 and the insulation 42 are preferably designed in the manner of a cylinder and an outer diameter of the insulation 42 is selected such that the conductor track contact element 28 can be inserted into the corresponding recessed groove 48 .

In addition, a magnet 54 is arranged in the carrier element 30 and is flush with the underside 32 of the carrier element 30 . The first element 8 may contain a soft magnetic material which is magnetic with magnets of any polarity. When bringing the Stromabneh in contact mer component 6 with the power supply component 4, the magnet 54 of the current collector component 6 adheres to the soft magnetic material of the power supply component 4 and thus ensures additional positional stability, i.e. the current collector component 6 does not move relative to the power supply component 4 as long as the two components 4.6 are in contact with each other, and preferably form an intact circuit.

Further developments of this system are also conceivable, which have a power supply component 4 with a first element 8 with three or more indentation grooves, the indentation grooves all having different depths from one another; and with three or more second elements 10-n. The number n of the second elements always corresponds to the number of indentation grooves with different depths.

Alternatively or additionally, it is also conceivable to design the deepening grooves 46, 48 with different widths. The second elements 10 arranged therein are then likewise formed with correspondingly different widths (one width per voltage). The additional “encoding” using the width can ensure that the correspondingly associated conductor track contact 28-1, 28-2 on a current collector component 6 also comes into contact with the associated conductor track 10-1, 10-2. This is shown schematically in the 6B-D shown. The width of the indentation grooves 46, 48 is selected in such a way that the indentation groove (in this case 48, for example), which is wider, is at the same time deeper than the indentation groove (in this case, 46, for example), which is narrower.

The conductor track contact element 28-1, which is provided for contacting the conductor track 12-1 in the recessed groove 46, is therefore shorter and narrower than the conductor track contact element 28-2, which is provided for contacting the conductor track 14-2 in the recessed groove 48.

In the event that the current collector component 6 is now misaligned with respect to the power supply component, as in 6C and 6D shown, there is no contact between the conductor track contact elements 28-1, 28-2 and the "wrong" conductor tracks 14-2, 12-1, since the conductor track contact element 28-1 is narrow enough to protrude into the recessed groove 48, however is too short to touch the conductor track 14-2 contained therein (see 6D ). The conductor track contact element 28-2 is too wide to be able to protrude into the narrow recessed groove 46 and therefore cannot come into contact with the conductor track 12-1 accommodated in the recessed groove 46 (see FIG 6C ).

7 shows a plan view of the system 2 according to the invention in a slightly modified form, in which the first element 8 of the power supply component does not contain any soft-magnetic material, but instead separate small plates 56 are arranged on the upper side 52 of the first element 8 .

8th shows a possible embodiment of an overcurrent protection device 58, wherein 8(a) a schematic representation of a constructive embodiment of the overcurrent protection device 58 shows; and in 8(b) an example circuit 60 is shown as it may be used for an overcurrent protection device 58. FIG.

The overcurrent protection device 58, as in 8(a) shown, is arranged in the power supply component 4 below a recess 18 and is in contact with the element which has the ground potential in the operating state, ie the first element 8 here. Should a consumer connected via this cutout 18 have a defect or cause a short circuit for other reasons, the remaining consumers electrically conductively coupled to the power supply component 4 via other cutouts are protected against a short circuit. Furthermore, by providing such an overcurrent protection device 58 for each of the recesses 18, 20, a failure of the entire power supply component due to just a single faulty consumer can be prevented.

8(b) shows a simple embodiment of the circuit 60, as it can be used to implement an overcurrent protection device 58, in the form of two transistors 62, 64.

It is also possible to provide only one overcurrent protection device per power supply component 4, which protects the entire power supply component 4 in the event of a short circuit in a connected load, but interrupts the power supply for all other correctly connected loads. Such an overcurrent protection device can be compared to a fuse in the house, which protects a circuit that extends over several rooms and "blows out" if one of the consumers connected to this circuit causes a short circuit and then all other connected consumers, such as .Lights in other rooms, no longer have electricity.

In the 8th The overcurrent protection device 58 shown is comparable to a fuse in the house, which protects a circuit that only extends through, for example, a single outlet in a room. If there is a short circuit at this outlet caused, this does not affect the power supply of a consumer that is connected via a different socket.

Furthermore, it is also conceivable to provide the overcurrent protection device in the current collector component 6 instead of in the power supply component 4 . However, such an overcurrent protection device only protects the consumer that is connected to the current consumer component 6, but not the power supply component 4.

9 and 10 12 show another conceivable embodiment of the power supply component 4. In this embodiment, the geometric assignment for the different voltages does not (only) take place via a different outer contour of the cutouts 18', 20', but (also) via the arrangement of the cutouts 18', 20' . 9 shows the arrangement of the recesses 18', 20' separately, whereas 10 this shows superimposed.

9 shows the first electrically conductive element 8 ′ on the left in the figure, which is shown here as a circular example. The recesses 18' are also circular and arranged in a square around the first element 8' such that the first element 8' is arranged in the center of the square so that all recesses 18' have the same distance to the first element 8' .

The second recesses 20' are arranged in a triangular shape around the first element 8', the triangular shape here being able to correspond both to a triangle with the apex pointing upwards and to a triangle with the point pointing downwards. The triangle is preferably an equilateral triangle, with the first element 8' being arranged at the center of this equilateral triangle, so that all the recesses 20' are equidistant from the first element 8'. The distance between the recesses 20' and the first element 8' is greater than the distance between the recesses 18' and the first element 8'.

10 shows a superimposed arrangement of the two in 9 illustrated arrangements of the first recesses 18' and the second recesses 20', the first recesses 18' being arranged in the free space between the second recesses 20' and the first element 8'. Such an arrangement prevents incorrect assignment of the ground contact and conductor track contact elements of the current collector component 4, for example due to oblique positioning, because all cutouts 18' and 29' are arranged at the same distance around the centrally positioned first element 8'.

It should be noted here that the first element 8′ does not necessarily have to be of circular design and does not necessarily have to be arranged exclusively in the middle of the recesses 18′, 20′. Only the contact surface for the mass contact element of the current collector component 6 has to be arranged centrally, ie in the middle. The shape of the recesses 18', 20' is also not limited to a circular shape and other shapes, such as triangular, square, polygonal, etc., are also conceivable.

Reference List

2

system

4

power supply component

6

pantograph component

8th

first electrically conductive element

10

second electrically conductive element

12

first track

14

second track

16

electrically insulating carrier material

17

Top of the second electrically conductive element

18

first recess

20

second recess

22

Top of the first electrically conductive element

24

fastener

26

electrically conductive ground contact element

28

electrically conductive conductor track contact element

30

electrically insulating carrier element

32

Underside of the support element

34

consumer

36

first through hole

38

second through hole

40

electrically conductive contact pin

42

electrical insulation

44

Bottom of electrical insulation

46

indentation groove

48

indentation groove

50

top of the insulation

52

Top of first element

54

magnet

56

Tile

58

overcurrent protection device

60

circuit

Claims (6)

Power supply component (4) for supplying power to one or more consumers (34), which can be connected to different power sources, having: at least one first electrically conductive element (8), which has the ground potential in the operating state, and at least two second electrically conductive elements (10-1, 10-2), which each have a conductor track (12-1; 14-2) and an electrically insulating carrier material (16), the conductor tracks (12-1, 14-2 ) have different voltages from one another in the operating state and are each accommodated in the respective electrically insulating carrier material (16) in such a way that the conductor tracks (12-1, 14-2) are each on an upper side (50) of the carrier material (16) at least from preside over wherein the at least one first electrically conductive element (8) is designed in the form of a block and has indentation grooves (46, 48) which extend along one direction and are arranged parallel to one another in a direction perpendicular to the direction of extension, first of the indentation grooves (46) having a first depth and second of the indentation grooves (48) having a second depth different from the first depth, wherein the first and second indentation grooves (46, 48) are arranged alternately and in the first indentation grooves (46) first of the at least two second electrically conductive elements (10-1) are arranged and second of the at least two second electrically conductive elements (10-2) are arranged in the second recess grooves (48). Power supply component (4) after claim 1 , wherein the at least one first electrically conductive element (8) further has third depression grooves with a third depth, and further has a third second electrically conductive element which has a conductor track and an electrically insulating carrier material, the conductor track of the third second electrical element having a has different voltages during operation than the other voltages and is accommodated in the electrically insulating carrier material of the third, second electrical element in such a way that the conductor track protrudes at least from an upper side of the carrier material. Power supply component (4) after claim 1 or 2 , wherein the at least one first electrically conductive element (8) comprises a soft magnetic material. System (2) for supplying power to one or more consumers (34) with a power supply component (4) according to one of Claims 1 until 3 and a current collector component (6) for supplying power to a consumer (34), the current collector component (6) having: an electrically conductive ground contact element (26) which prepares for contacting the at least one first electrically conductive element (8) of the power supply component (4). is, at least one electrically conductive conductor track contact element (28, 28-1, 28-2) which is prepared for contacting a conductor track (12-1, 14-2) of the power supply component (4), and a carrier element (30) which consists of an electrically insulating material, the carrier element (30) having an underside (32) which is prepared for contacting the power supply component (4), the ground contact element (26) being accommodated in the carrier element (30) in such a way that it is flush is arranged on the underside (32), and wherein the at least one electrically conductive conductor track contact element (28, 28-1, 28-2) has an electrically conductive contact pin (40) b electrical insulation (42) is arranged on its lateral surface, and the at least one electrically conductive conductor track contact element (28, 28-1, 28-2) is accommodated in the carrier element (30) in such a way that it can be pulled out from the underside (32) of the carrier element (30) protrudes in such a way that between the at least one electrically conductive conductor track contact element (28, 28-1, 28-2) and a conductor track (12-1; 14-2) of the power supply component (4) a contact can be formed. System (2) for power supply claim 4 , wherein the current collector component (6) is also formed with a second electrically conductive conductor track contact element (28-1, 28-2), which is prepared for contacting a conductor track (12-1; 14-2) of the power supply component (4), wherein the the second electrically conductive conductor track contact element (28-1, 28-2) has an electrically conductive contact pin (40) on the outer surface of which electrical insulation (42) is arranged, and the second electrically conductive conductor track contact element (28-1, 28-2) so is accommodated in the carrier element (30) in such a way that it protrudes from the underside (32) of the carrier element (30) in such a way that between the second electrically conductive conductor track contact element (28-1, 28-2) and a conductor track (12-1; 14 -2) the power supply component (4) a contact can be formed. System (2) for power supply claim 4 or 5 , wherein in the carrier element (30) further at least one magnet (54) is accommodated.

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