DE102016203125B4 - Electrical system for a motor vehicle with an electromechanical switching device and a holding device and motor vehicle with it - Google Patents

Abstract

Electrical system for a motor vehicle, comprising an electromechanical switching device (20, 30) and a holding device (58) for the electromechanical switching device (20, 30), wherein the holding device (58) has a fastening unit (56) for connecting to a fastening element (54) a housing (12, 32) of the electromechanical switching device (20, 30), wherein the electromechanical switching device (20, 30) the housing (12, 32), which at least a first and a second power terminal (14, 16) and at least two Control terminals, at least one in the housing (12, 32) arranged switching unit (24) having a first and a second switching terminal (26, 28), wherein the first switching terminal (26) by means of a first electrical line (34) to the first Power terminal (14) and the second switching terminal (28) is connected by means of a second electrical line (36) to the second power terminal (16), wob ei the switching unit (24) has an electromechanical switching element (38) connected to the switching terminals (26, 28) for alternately establishing and interrupting an electrical connection between the first and second switching terminals (26, 28), resulting in a respective switching state, and an electromechanical actuator (40) arranged in the housing (12, 32) and connected to the at least two control terminals for actuating the switching element (38) in order in each case to set one of the switching states, the housing (12, 32) being mounted on an outside ( 42) of a housing wall (44) has a contact surface (46) for thermally coupling a housing-external heat sink (48) and on one of the outer side (42) opposite inner side (50) of the housing wall (44) has a heat conducting element (52) for internal heat dissipation of housing the switching unit (24) and / or the actuator (40) to the contact surface (46), wherein a further Kontaktf for the thermal coupling of a further external heat sink by a fastening element (54) of the housing (12, 32) is formed, wherein to the power terminals (14, 16) each electrical lines (18, 22) of the electrical system are connected, with which the electromechanical switching device (20, 30) is electrically connected to the electrical system, and wherein the holding device (58) with the heat sink (48) thermally coupled heat transfer surface for thermal contacting the contact surface (46) of the housing (12, 32) of the electromechanical switching device (20, 30) and for dissipating heat from the contact surface (46) towards the heat sink (48).

Description

The present invention relates to an electrical system for a motor vehicle, comprising an electromechanical switching device and a holding device for the electromechanical switching device, wherein the holding device has a fastening unit for connecting to a fastening element of a housing of the electromechanical switching device. Finally, the invention also relates to a motor vehicle.

Circuit devices of the generic type, electrical systems with such switching devices and motor vehicles are widely known in the art, so it does not require a separate printed evidence for this reason basically. Electromechanical switching devices of the generic type are widely used in electrical systems, such as those electrical systems of motor vehicles, in particular electrically driven motor vehicles such as electric vehicles, hybrid vehicles and / or the like. Often, such prior art electromechanical switching devices are also referred to as a "contactor," "relay," or the like. Electromechanical switching devices are characterized inter alia by the fact that they have one or more electromechanical switching contacts, by means of which an electrical connection between associated power terminals can be produced due to a mechanical movement. Depending on the switching state, there is an electrical connection or it is interrupted. Depending on the electrical power to be switched, the corresponding switching contacts are designed.

An electromechanical switching device may comprise a housing, which has at least one first and one second power connection and at least two control connections, at least one switching unit arranged in the housing, which has a first and a second switching connection, wherein the first switching connection is connected to the first power connection by means of a first electrical line and the second switching terminal is connected to the second power terminal by means of a second electrical lead, the switching unit having an electromechanical switching element connected to the switching terminals for alternately establishing and interrupting an electrical connection between the first and second switching terminals, resulting in a respective switching state, and an arranged in the housing and connected to the at least two control terminals electromechanical actuator for actuating the switching element to each other s to set one of the switching states.

For the purpose of setting a predeterminable switching state, the electromechanical switching device on the electromechanical actuator, which mechanically drives the switching contact, so that the electromechanical switching device is able to take the respective switching state.

In the case of large powers to be switched and / or voltages and / or currents, normally contactors, in particular contactors, are used. Otherwise, relays are used. In particular, in a contactor results in normal operation, a heating, which is determined by a design of the electrical system in which the contactor is operated. In particular, a current load, especially a current load of the switching contact, leads to a corresponding heating. So that overload conditions can be avoided in the contactor, the manufacturer's nominal values, for example, a rated current, a rated voltage or the like specified for which the contactor designed or for which it is dimensioned in terms of design. In order to define a load capacity of the contactor with regard to rated power or rated voltage, the contactor manufacturer specifies maximum current values (peak currents) as well as time durations for such current values in addition to the above-mentioned nominal values or rated values for short-time loads, which should be taken into account when dimensioning the electrical system. Usually, such time periods are in the range of a few seconds to a few minutes. The peak currents are usually currents that exceed the rated current or rated current of the contactor. A peak current causes an additional strong temperature entry in the contactor, which is why corresponding load limits must be observed, which are specified by the manufacturer. As a rule, the values for such overload conditions are precisely specified by the respective contactor manufacturer within narrow limits.

An important factor that limits the maximum peak currents and durations for this, results from the disproportionate temperature entry in the contactor itself, which is caused by this. Here, the value of the respective current as well as a contact resistance of the contact of the contactor as well as in the contactor existing electrical conductors between power connections and the switching contact within the contactor is to be observed.

Among other things, thermal resistance transition values such as R _th = (T ₂ -T ₁ ) / Q [K / W] between the points of origin of the thermal energy input are very limiting and decisive for determining maximum peak currents of the contactor and durations thereof Heat sources to which the temperature T _{2 is assigned} as a thermal energy source, and the conductor contacting the contactor or the power connection, which provides a thermal sink of the contactor and the temperature T _{1 is} assigned.

1. 1. Konduktion (Wärmeleitung) R_th = d/(lambda x A)
2. 2. Konvektion (Luft) R_th = 1/(a A) K/W
3. 3. Strahlung (Luft) R_th = ΔT/Q K/W

Thermal cooling paths over which the contactor can be cooled are in particular:

1. 1. Conduction (heat conduction) R _th = d / (lambda x A)
2. 2. Convection (air) R _th = 1 / (a A) K / W
3. 3. Radiation (air) R _th = ΔT / QK / W

The thermal cooling paths 2 , Convection and 3 , Due to the relatively small possible emission area and the small installation space, radiation can be neglected compared to the heat conduction effect (conduction), in particular in motor vehicles. The essential Entwärmungspfad, over which the unwanted heat loss can be dissipated, is thus the conductive heat dissipation path d for conductor contacting at the power terminals, for example, with a thermal conductivity lamba. Usually, the power connections of the contactor are connected by means of thick electrical conductors or busbars to the electrical system, for example by means of a screw fastening, a clamping attachment and / or the like, which makes it possible to provide a good heat dissipation. Thus, the larger the cross-section A of the line connected to the power connection of the contactor, the greater the heat dissipation, resulting in a corresponding increase of peak current values and durations thereof, which are preferably specified manufacturer-specific. A contactor of the generic type, in which the power terminals are used for the purpose of cooling, for example, from WO 01/86681 A1 known.

Although this procedure has been proven in the prior art, the possibilities of heat dissipation based thereon are limited. Particularly in the case of motor vehicles, the desire for greater short-term loads exceeds the previous values, because short-time loads in normal operation represent an important type of load for the contactor, especially in the case of electrical systems of motor vehicles.

In addition, the reveals DE 10 2011 113 929 A1 an electromechanical circuit structure and a method for its preparation and its application. Further, the DE 199 32 441 A1 a device for cooling semiconductor devices when load peaks occur. Furthermore, the disclosure EP 2 648 198 A1 an integrated planar electromechanical switch. The US 4,060,847 discloses a cooling arrangement for an electrical circuit breaker. The US 6,271,740 B1 discloses a reed relay. Finally, the reveals DE 11 2013 005 900 T5 an electromagnetic switch with stable moving contact.

It is therefore the object of the invention to improve a generic electromechanical switching device with respect to a short-term load on.

As a solution, the invention proposes an electrical system and a motor vehicle according to the independent claims.

Further advantageous embodiments will become apparent from the features of the dependent claims.

On the plant side is proposed in particular for a generic electrical system that the electromechanical switching device is formed according to the invention and the holding device with the heat sink thermally coupled heat removal surface for thermal contacting a contact surface of the housing of the electromechanical switching device and for dissipating heat from the contact surface towards the heat sink having.

Motor vehicle side is proposed with the invention that the motor vehicle has an electrical system according to the invention.

With regard to a generic electromechanical switching device, it is proposed that the housing on an outer side of a housing wall has a contact surface for thermally coupling a housing-external heat sink and a heat-conducting element on the inside of the housing wall opposite to the outside for guiding heat from the switching unit and / or the actuator Contact surface has.

An important aspect of the invention is therefore based on providing at least one further heat dissipation path in addition to the cooling already enabled via the power connection, by means of which it is possible to dissipate heat in such a complementary manner that a short-term load, for example a short-term overload of the contactor, can be further improved. This means that a value for the peak current can be increased and / or a value for a period of time can be extended accordingly. This is achieved by the invention by at least one additional heat dissipation path, which by means of the contact surface of the Housing is provided in conjunction with the heat conducting element inside the housing. This makes it possible to dissipate additional heat from both the switching unit and the actuator to a complementary heat dissipation path and thereby provide additional cooling. This makes it possible to provide higher overload conditions through the contactor.

The housing of the electromechanical switching device provides a receiving space in which the units and elements of the electromechanical switching device are arranged. In order to be able to electrically couple the electromechanical switching device with the electrical system, the power connections are provided. In accordance with a switching function, a number of corresponding power terminals are provided, that is, at least one first and one second power connection, in order to be able to form a single-pole switching unit. In addition, alternatively, multi-pole switching units may be provided, which may be formed, for example, as an opener, as a closer or as a changeover. As already explained above, the power connections also serve to dissipate heat, in particular heat dissipation from the switching unit. Insofar, inside the housing corresponding first and second electrical lines are provided, which are connected to the at least two power terminals with a first and a second switching terminal of the switching unit arranged in the housing. Of course, the number of lines and the switching connections, as well as possibly the number of power connections, depends on the switching function which the switching unit or the electromechanical switching device is capable of providing. Via the electrical lines there is a heat dissipation or heat transfer from the switching unit to the power terminals.

The switching unit comprises at least one electromechanical switching element which, in cooperation with one or more switching contacts, provides the desired switching function. The switching function generally consists in alternately establishing and interrupting an electrical connection between the relevant switching connections, for example the first and the second switching connection of the switching unit, resulting in a respective switching state. The switching element is usually formed at least partially electrically conductive and preferably electrically connected at one end to the first switching connection. A second end is movably arranged so that it is able to contact the second switching port depending on the switching state. For this purpose, the switching element is mounted correspondingly movable. So that the switching element can assume the position or position corresponding to the desired switching state, it is mechanically connected to the electromechanical actuator which is connected to the two control terminals and mechanically actuates the switching element in order to be able to set the respective switching state. For this purpose, the actuator is acted upon via the control terminals with a corresponding electrical signal: The electromechanical actuator may be formed on an electrostatic base, inductive base and / or the like. Usually, it provides according to the respective switching state, a lifting and / or rotational movement, by means of which the electromechanical switching element can be driven in the desired manner.

The housing of the electromechanical switching device is often formed from a plastic, a metal and / or the like. If the housing is formed from an electrically conductive material, the power terminals and the control terminals are arranged in an electrically insulated manner above the housing. Through the housing, the switching unit and the actuator are usually protected from external influences. In addition, the housing may also have a spark-quenching chamber and / or the like in order to suppress or extinguish, for example, sparks or arcs occurring during a switching operation of the switching unit.

The housing has a housing wall which, inter alia, preferably provides a receiving space for the units and elements of the electromechanical switching device. Among other things, the power terminals may be arranged on the housing wall, so that they are accessible from outside the housing for the purpose of connecting the electromechanical switching device to the electrical system. The power connections can be formed, for example, by contact lugs, contact terminals, in particular screw terminals and / or the like. The housing wall according to the invention provides the contact surface for the thermal coupling of a housing-external heat sink. The housing-external heat sink may be any device that can absorb heat and / or can dissipate. Such heat sinks may be, for example, a heat sink, a fluid-flow heat exchanger, a holding frame and / or the like. Preferably, the contact surface is formed just with the lowest possible roughness, so that a good thermal coupling of the housing-external heat sink can be achieved. Of course, the contact surface may also be curved when a contacting mating surface of the housing-external heat sink is designed to be complementary.

On the outside of the housing wall opposite the inside of the housing wall, a heat-conducting element is provided for guiding heat on the inside of the housing from the switching unit and / or the actuator to the contact surface. The heat-conducting element may, for example, be a gap filler, that is to say an elastic material which thermally contacts the switching unit and / or the actuator on the one hand and the side of the housing wall opposite the inside of the contact surface on the other hand. As a result, an additional heat dissipation path is created so that further heat dissipation possibilities are created by the switching unit as well as by the actuator in addition to the already existing heat dissipation possibilities. The heat-conducting element can be formed for example by a material such as silicone, rubber and / or the like. Alternatively or additionally, the heat-conducting element can of course also be formed from a rigid material, for example a metal, an electrically insulating ceramic such as aluminum oxide or the like. Among other things, aluminum oxide is characterized by providing good thermal conductivity with high electrical insulation capability. Such a heat-conducting element is therefore particularly suitable when the electromechanical switching device is subjected to high electrical voltages.

However, the invention is not reduced to providing only a single contact surface. Of course, a plurality of contact surfaces can be provided, which can be determined according to design requirements, for example, by the electrical system in which the electromechanical switching device is to be installed, or the like. By means of the invention, a reduced thermal resistance R _th with respect to the conductive thermal heat dissipation path can be achieved from the inside of the electromechanical switching device outwardly by additionally provided defined thermal contact surfaces on the electromechanical switching device, for example directly a chassis, for example an aluminum chassis, or Contact a cooling plate on which the electromechanical switching device is mounted. In the electromechanical switching device itself is preferably by appropriate design measures a high-voltage low-voltage insulated, thermally optimized as possible heat transfer from the respective heat source to ensure the predetermined contact surfaces according to the invention.

Preferably, the remote station with which the electromechanical switching device is connected, designed correspondingly geometrically suitable to allow the best possible thermal connection of the electromechanical switching device. In order to be able to further optimize a heat transfer resistance between the contact surface and the corresponding mating surface of the heat sink, heat transfer resistance reducing substances, for example thermally conductive fluid pastes, heat conducting foils or the like may be arranged between the contacting surfaces. It proves to be particularly advantageous if such a substance has a phase-changing material which, for example, is dry and solid at room temperature and softens with increasing heating and wets the contact surfaces as completely as possible.

With the invention it can be achieved that peak currents and time periods for this can be specified higher by the manufacturer. In addition, defined heat dissipation paths with respect to the electromechanical switching device can be achieved. As a result, the heat at the electromechanical switching device or its housing can be provided at predetermined locations, so that the electromechanical switching device also only needs to be designed accordingly with regard to the thermal load. Thus, areas of higher and lower thermal stress regions can be formed in the electromechanical switching device, which offer advantages in terms of the design of the electromechanical switching device. Furthermore, the heat dissipation of the electromechanical switching device can be made more independent of the heat dissipation via connected lines. It is therefore no longer necessary to choose a conductor cross-section for a connection to the power connections that is greater than the current carrying capacity required to provide the required cooling of the electromechanical switching device. This can now be achieved via the contact surface. Overall, a longer service life or a larger number of switching cycles with respect to the electromechanical switching device can be achieved with the invention, in particular because a reduced thermal stress can be achieved. In addition, the invention is of course also suitable for retrofitting existing electrical systems and motor vehicles, in particular because additional installation effort can be saved, for example, because an existing mechanical recording of the electrical system already can provide a corresponding heat sink.

The contact surface is at least partially formed by a fastening element of the housing. With the fastening element, the housing in the electrical system or in the motor vehicle can be fastened in a predeterminable manner. The fastener may, for example, a tab, a flange, but also a Pin, in particular a threaded pin and / or the like. This makes it possible to provide the contact surface in a simple manner.

According to a further development, it is proposed that the contact surface is arranged at least partially adjacent to the fastening element of the housing in an area which is unused for attachment of the switching device. This makes it possible to additionally provide the heat sink in a simple manner in an electrical system or a motor vehicle. The attachment, which is already provided in the electrical system or the motor vehicle for the electromechanical switching element, can be largely retained unchanged. This is particularly advantageous for retrofitting.

According to one embodiment, it is proposed that the actuator has a lifting magnet coil with a laminated core, wherein the laminated core is thermally coupled as a heat conducting element with the contact surface. This embodiment makes it possible to form the heat-conducting element at the same time with elements already present in the electromechanical switching device, in this case the actuator. There is no additional element required in this embodiment. By simple design measures on the electromechanical switching device of the additional thermal heat dissipation path can be achieved.

It has proven to be advantageous if the heat conducting element is designed to provide a predetermined thermal conductivity which is greater than about 1 W / mK, and / or the heat conducting element is designed to provide a predetermined heat capacity which is greater than 0.4 kJ / kgK , With the heat capacity, a high overload capacity can be achieved, in particular with very short peak currents. With its heat capacity, the heat-conducting element can at least partially absorb the heat of the heat source and provide it for discharge. This is extremely advantageous for short pulse loads due to currents. With regard to the cooling, it has been found that the aforementioned thermal conductivity is advantageous for guiding the heat from the heat source to the contact surface.

It proves to be particularly advantageous if the heat-conducting element has a cavity with a substance which undergoes a phase transformation during normal operation when heat is absorbed. As a result, the heat-conducting element can provide a high heat capacity and further improve the short-term load, in particular with regard to peak currents and time periods. Such a substance may be, for example, a salt which is liquefied at low temperatures or the like.

It is also proposed that the housing is made of aluminum by means of injection molding or die casting. This not only a very robust housing can be realized, but it can also be designed very cost-effective beyond. Alternatively, the housing may also be made of a die-cast zinc. This makes it possible to continue to apply manufacturing methods already used for electromechanical switching devices.

With regard to the electrical system is provided that it has a holding device for the electromechanical switching device. The holding device may be, for example, a chassis, a cooling plate, a metal plate or the like. Preferably, aluminum is used as the material, which has a high thermal conductivity and a comparatively low specific weight in comparison to other materials with a corresponding thermal conductivity. The holding device further comprises a fastening unit for connecting to the fastening element of the housing of the electromechanical switching device. The fastening unit can be formed, for example, by a rail against which a fastening tab or a flange of the housing rests and which are mechanically connected to one another by means of a rivet, a screw, a clamping element and / or the like.

The holding device furthermore has a heat removal surface that can be thermally coupled with a heat sink for thermal contacting of the contact surface of the housing of the electromechanical switching device and for dissipating heat from the contact surface to the heat sink. The heat dissipation surface is preferably formed corresponding to the contact surface, so that the largest possible contact can be provided. The heat dissipation surface can be formed, for example, by the chassis, the cooling plate or the metal plate. For example, the heat dissipation surface may also be formed by a heat sink, which is thermally coupled to the heat dissipation surface or provides these.

Further advantages and features will become apparent according to the following embodiments, taking into account the accompanying figures. In the figures, like reference numerals designate like components and functions.

• 1 in einer schematischen perspektivischen Darstellung ein Schütz gemäß dem Stand der Technik,
• 2 eine schematische perspektivische Darstellung eines Schützes gemäß einer nicht beanspruchten Ausführungsform, und und
• 3 in einer schematisch perspektivischen Darstellung eine Ausgestaltung eines Schützes gemäß der Erfindung mit einem Kühlkörper, der mit einer Wärmeabführfläche eine Kontaktfläche des Gehäuses des Schützes kontaktiert.

Show it:

• 1 in a schematic perspective view of a contactor according to the prior art,
• 2 a schematic perspective view of a contactor according to an unclaimed embodiment, and and
• 3 in a schematic perspective view of an embodiment of a contactor according to the invention with a heat sink, which contacts with a heat dissipation surface, a contact surface of the housing of the contactor.

1 shows in a perspective and schematic representation of a contactor 10 as electromechanical switching device according to the prior art. The contactor 10 has a housing 12 on, which has a first and a second power connection 14 . 16 as well as two in 1 Has not shown control terminals. Furthermore, a dashed line in the housing 12 arranged switching unit 24 shown having a first and a second switching connection 26 . 28 having. The first switching connection 26 is by means of a first electrical line 34 to the first power connection 14 and the second switching terminal 28 is by means of a second electrical line 36 to the second power connection 16 connected. The switching unit 24 indicates a to the switching terminals 26 . 28 connected electromechanical switching element 38 for alternately establishing and interrupting an electrical connection between the first and second switching terminals 26 . 28 on, resulting in a respective switching state. The switching unit 24 is designed here as a closer. The switching unit 24 with their switching connections 26 . 28 as well as the lines 34 . 36 are in one of a housing wall 44 of the housing 12 formed cavity arranged. The power connections 14 . 16 on the other hand are outside the cavity on an outer surface 42 the housing wall 44 arranged so that they for electrical connection to a non-illustrated electrical system from outside the housing 12 are accessible.

In the cavity of the housing 12 is also an actuator 40 for mechanically actuating the switching element 38 arranged to set each one of the switching states. The actuator 40 is presently formed by a solenoid coil with a laminated core. An armature movably mounted in the lifting magnet coil couples the electromechanical switching element, which is likewise movably mounted 38 , The anchor and the laminated core are in the 1 not shown.

To the power connections 14 . 16 are each electrical lines 18 . 22 connected to the electrical system with which the contactor 10 is electrically connected to the electrical system, not shown.

The housing 12 also points to the outer wall 42 opposite each a flange 54 as a fastener of the housing 12 on. Every flange 54 is with a carrier 56 a not shown aluminum chassis mechanically connected. The connection is in the present case carried out by a screw connection, not shown.

2 now shows a first embodiment of a contactor 20 according to the invention, which on the contactor 10 according to 1 based. Also the contactor 20 has a housing as electromechanical switching device 12 which is essentially the housing in terms of its construction 12 corresponds, as it already did to 1 has been explained. Also, the active elements enclosed by the housing, such as the switching unit 24 and the actuator 40 as well as the power connections 14 and 16 according to what is already for 1 why, in this regard, the relevant comments on the 1 is referenced. Incidentally, the same applies to the mounting flanges 54 as well as the lines 18 . 22 with which the contactor 20 connected to the electrical system. In the present case is the housing 12 made of die-cast aluminum.

Notwithstanding the embodiment according to the prior art, as in 1 is shown, the housing has 12 on its outside 42 a housing wall 44 a contact surface 46 for thermally coupling a housing-external heat sink 48 and on one of the outside 42 opposite inside 50 the housing wall 44 a heat conducting element 52 for intra-housing conduction of heat from the switching unit 24 and the actuator 40 to the contact surface 46 on. In the present case is the contact surface 46 on the outside 42 the housing wall 44 formed by a special surface treatment, so that a good thermal contact is possible. On the opposite inside 50 the housing wall 44 is as a heat conducting element 52 provided a gap filler, which is formed in this case of silicone. This makes it possible both the actuator 40 as well as the switching unit 24 thermally couple, because the gap filler 52 in the present case also has insulating properties, whereby the intended operation with regard to the electrical properties of the contactor 20 is essentially not affected. So there is a heat flow through the gap filler 52 through the housing wall 44 to the contact surface 46 where a suitable heat sink 48 thermally coupled to provide an additional heat dissipation path. This allows improved cooling of the contactor 20 can be achieved, whereby peak currents can handle correspondingly higher and a time can be extended accordingly.

3 shows a further embodiment of a contactor 30 as electromechanical switching device according to the invention, which basically according to the first embodiment according to 2 Therefore, in addition to the comments on the embodiment according to 2 is referenced.

In contrast to the embodiment according to 2 has the embodiment according to 3 mounting flanges 54 on top of the case 32 of the contactor 30 are arranged. In the present case it is provided that the contact surface 46 immediately adjacent to the flange 54 of the housing 32 is trained. A heat sink is here by the Aluchassis 56 provided.

In addition, another contact surface 46 adjacent to the flange 54 of the housing 32 in one for the attachment of the switching device 30 unused area arranged. How out 3 is apparent here is as a heat sink 48 arranged a cooling plate, which with a heat dissipation surface, the contact surface 46 of the housing 32 contacted and heat from the contact surface 46 towards the heat sink 48 dissipates. The heat sink 48 in the present case comprises a heat sink 60 , which has not further designated cooling fins.

The embodiments described above are merely illustrative of the invention and are not limiting for this. Thus, of course, the arrangement of the contact surface and the heat-conducting element vary without departing from the spirit of the invention. Of course, more than just a single contact surface and a single heat conducting element can be provided. In addition, phase-changing materials can be applied, which are dry or solid, for example, at room temperature and soften with increasing warming and largely completely wet the contact surface or the heat removal surface. Thereby, an improved heat transfer between the surfaces can be achieved.

Overall, the invention achieves that a value for a peak current or a value for a period of time thereof can be increased due to the improved cooling of the electromechanical switching device. In addition, defined heat dissipation paths can be created within the electromechanical switching device, so that thermally little stressed areas can be created in the housing of the electromechanical switching device. In addition, the heat dissipation paths created thereby are independent of connected lines, by means of which the electromechanical switching device is connected to the electrical system. Overall, a longer life of the electromechanical switching device can be achieved by the invention. This can be achieved without the need for additional installation effort in the assembly of the electromechanical switching device needs.

In addition, it should be noted that the advantages and features described for the electromechanical switching device also apply to an electrical system with such an electromechanical switching device and for a motor vehicle hereby.

The embodiments are only illustrative of the invention and are not limiting for these. Of course, functions, in particular also with regard to the configuration of the heat-conducting element, can vary without departing from the spirit of the invention. Finally, it should be noted that the advantages and features and embodiments described for the electromechanical switching device according to the invention apply equally to the corresponding electrical system and the corresponding motor vehicle and vice versa. Furthermore, corresponding device features and vice versa can be provided for device features.

Claims (7)

Electrical system for a motor vehicle, comprising an electromechanical switching device (20, 30) and a holding device (58) for the electromechanical switching device (20, 30), wherein the holding device (58) has a fastening unit (56) for connecting to a fastening element (54) a housing (12, 32) of the electromechanical switching device (20, 30), wherein the electromechanical switching device (20, 30) the housing (12, 32), which at least a first and a second power terminal (14, 16) and at least two Control terminals, at least one in the housing (12, 32) arranged switching unit (24) having a first and a second switching terminal (26, 28), wherein the first switching terminal (26) by means of a first electrical line (34) to the first Power terminal (14) and the second switching terminal (28) is connected by means of a second electrical line (36) to the second power terminal (16), wob ei the switching unit (24) has an electromechanical switching element (38) connected to the switching terminals (26, 28) for alternately establishing and interrupting an electrical connection between the first and second switching terminals (26, 28), resulting in a respective switching state, and an electromechanical actuator (40) arranged in the housing (12, 32) and connected to the at least two control terminals for actuating the switching element (38) in order in each case to set one of the switching states, the housing (12, 32) being mounted on an outside ( 42) of a housing wall (44) has a contact surface (46) for thermal coupling of a housing-external heat sink (48) and on a side (50) of the housing wall (44) opposite the outside (42) a heat-conducting element (52) for conducting heat on the inside of the housing from the switching unit (24) and / or the actuator (40) to the contact surface (46), wherein a further contact surface for thermally coupling a further outer housing heat sink by a fastening element (54) of the housing (12, 32) is formed, wherein to the power terminals (14, 16) respectively electrical lines (18, 22 ) are connected to the electrical system, with which the electromechanical switching device (20, 30) is electrically connected to the electrical system, and wherein the holding device (58) with the heat sink (48) thermally coupled heat removal surface for thermal contacting the contact surface (46) the housing (12, 32) of the electromechanical switching device (20, 30) and for dissipating heat from the Contact surface (46) toward the heat sink (48). Electrical system after Claim 1 , characterized in that the heat dissipation surface is thermally coupled to a heat sink (60). Electrical system after Claim 1 or 2 , characterized in that the actuator (40) comprises a Hubmagrietspule with a laminated core, wherein the laminated core is thermally coupled as a heat conducting element (52) with the contact surface (46). Electrical system according to one of the Claims 1 to 3 characterized in that the heat conducting element (52) is adapted to provide a predetermined thermal conductivity greater than 1 W / m K, and / or the heat conducting element (52) is adapted to provide a predetermined heat capacity greater than 0, 4 kJ / kg K. Electrical system according to one of the Claims 1 to 4 , characterized in that the heat-conducting element (52) has a cavity with a substance which undergoes a phase transformation during intended operation when heat is absorbed. Electrical system according to one of the Claims 1 to 5 , characterized in that the housing (12, 32) is made of aluminum by means of injection molding or die casting. Motor vehicle with an electrical system according to one of the preceding claims.

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