DE102019205236A1 - Sensor device, base part and busbar sensor arrangement - Google Patents

Abstract

Shown and described is a sensor device (3) for receiving a busbar (5) with a base part (9) with a receiving surface that has at least a section of a channel with a base that extends along a channel plane for receiving a section of the busbar ( 5), and a first fastening means (29), a flat printed circuit board (13) with a first and a second contact surface (49, 39) which run parallel to one another, and a second fastening means (41) and a sensor (15), which is connected to the printed circuit board (13) on the side of the second contact surface (39), wherein the first and second fastening means (29, 41) can be connected to one another, the sensor device (3) being in a connected state when the first and second fastening means (29, 41) are connected to one another, wherein in the connected state the first contact surface (49) faces the channel and the second contact surface (39) faces the channel is turned away, the channel plane runs parallel to the first contact surface (49) and a connecting force acts perpendicular to the channel plane between the first and second fastening means (29, 41), the connecting force being greater than a predetermined minimum connecting force.

Description

The present invention relates to a sensor device for receiving a busbar, a base part for a sensor device and a busbar sensor arrangement with a sensor device.

Sensor devices with sensors are known from the prior art.

For example, sensor devices are used to measure current levels of an electrical current in a busbar. In order to ensure the highest possible measuring accuracy, the sensors of the sensor devices must be positioned as precisely as possible to the corresponding busbar.

If electrical currents in busbars of converters in the automotive environment are measured with sensor devices, then the sensor devices and the busbars can be exposed to high vibration loads, as a result of which high forces can act on the sensor devices and the busbars. These high forces can mean that the position of the sensor of the sensor device and the position of the busbar can change with respect to one another. This is the case in particular when the busbar does not extend within a circuit board to which the sensor of the sensor device is connected.

It is therefore the object of the present invention to provide a sensor device for receiving a busbar, wherein a sensor of the sensor device can be positioned as exactly as possible to the corresponding busbar and this exact positioning is ensured even with high vibration loads.

According to a first aspect of the invention, the stated object is achieved by a sensor device having the features of patent claim 1. The sensor device is designed to accommodate a busbar. The sensor device has a base part with a receiving surface and a first fastening means. The receiving surface forms at least a section of a channel for receiving a section of the busbar. The channel has a floor that extends along a channel plane. The sensor device has a flat printed circuit board. The circuit board has a first and a second contact surface and a second fastening means. The first and second contact surfaces run parallel to one another. The sensor device has a sensor. The sensor is connected to the circuit board on the side of the second contact surface. The first and second fastening means can be connected to one another. The sensor device is in a connected state when the first and second fastening means are connected to one another. In the connected state, the first contact surface faces the channel and the second contact surface faces away from the channel. In addition, in the connected state, the channel plane runs parallel to the first contact surface and a connecting force acts perpendicular to the channel plane between the first and second fastening means. The connection force is greater than a predetermined minimum connection force.

The base part has a receiving surface which forms at least a section of the channel for receiving a section of the busbar. The busbar can rest against the receiving surface at least in sections and thus be held by the receiving surface. The receiving surface of the base part therefore enables the busbar to be positioned precisely in relation to the base part. Precise positioning of the busbar in relation to the base part can in particular be made possible by a form-fitting contact of the busbar on the receiving surface.

The sensor is connected to the circuit board. In particular, the sensor is mechanically and electrically connected to the circuit board. When connecting the sensor to the circuit board, exact positioning of the sensor relative to the circuit board can be ensured.

In the connection state, the first and second fastening means are connected to one another. A connection of the first fastening means to the second fastening means ensures that the base part and the circuit board are fastened to one another in the connected state.

In the connected state, the second contact surface faces away from the channel, so that the sensor, which is connected to the circuit board on the side of the second contact surface, is arranged on the side of the circuit board facing away from the channel. The first contact surface of the circuit board runs parallel to the second contact surface, so that an exact positioning of the sensor relative to the first contact surface of the circuit board is guaranteed.

In the connected state, the channel plane runs parallel to the first contact surface, so that the base, which extends along the channel plane, extends parallel to the first contact surface. If a section of the busbar is received by the duct in the connected state, exact positioning of the section of the busbar in relation to the duct plane and thus also in relation to the sensor is ensured.

In the connection state, a connection force acts perpendicular to the channel plane between the first and second fastening means. The connection force ensures the connection state of the sensor device. The connection force is greater than a predetermined minimum connection force. The predetermined minimum connection force ensures that the connection force acting between the first and second fastening means is sufficiently high so that the connection state is guaranteed even with high vibration loads.

In summary, it can be stated that a sensor device is provided for receiving a busbar, wherein a sensor of the sensor devices can be positioned exactly to the corresponding busbar and this exact positioning is ensured even with high vibration loads.

The busbar can be a busbar of a power converter. The busbar can be electrically coupled to the remaining part of the converter. The converter can be a converter for power electronics in a motor vehicle. The converter is preferably an inverter or an AC converter. The power converter can also be referred to as an inverter or drive inverter or drive converter. The converter can also be a DC / DC converter or a rectifier.

The base part can comprise plastic and / or be formed at least in sections from plastic. Plastic has a low density, so that the base part can have a particularly low weight. The base part can be an injection-molded part, in particular a plastic injection-molded part, so that the base part can be produced inexpensively in different shapes and with different surface structures.

The base part is preferably connected to the converter only via the busbar or, if several busbars can be accommodated by the base part, via these busbars as the only mechanically rigid connection. In addition, the base part can be connected to the power converter via cables that can provide a non-rigid connection. As a result, a mechanical decoupling between the base part and the converter can be provided such that the base part can vibrate mechanically together with the busbar, so that the base part can maintain its position relative to the busbar even under high vibration loads.

The channel has a floor that extends along a channel plane. The bottom can be formed at least in sections by the receiving surface. If the bottom is formed by the receiving surface, a form fit perpendicular to the channel plane can be provided between the section of the busbar and the receiving surface. The channel can have two walls that extend away from the floor and perpendicular to the channel plane so that the busbar can be received between the walls. One or both of the two walls can be formed by the receiving surface. If one of the two walls is formed by the receiving surface, a form fit in a direction parallel to the channel planes can be provided between the section of the busbar and the receiving surface. If both of the two walls are formed by the receiving surface, a form fit can be provided between the section of the busbar and the receiving surface in two opposite directions parallel to the channel planes.

The circuit board is flat. The evenness of the printed circuit board enables sections that extend uniformly flat both on the side of the first contact surface of the circuit board and on the side of the second contact surface of the circuit board. The sensor can be arranged, for example, on a section extending evenly flat on the side of the second contact surface of the circuit board.

The sensor can be a current sensor in order to measure a current strength of an electric current in the busbar via the magnetic flux density caused by the electric current. The sensor can be an AMR sensor, in particular an AMR current sensor. An AMR sensor is based on the anisotropic magnetoresistive effect. An AMR sensor enables particularly precise, fast and potential-free measurements.

The first and second fastening means can be connected to one another and are connected to one another in the connected state of the sensor device. The first and second fastening means can be releasably connected to one another. A releasable connection of the first and second fastening means enables the sensor device to be reusable. The first and second fastening means can be permanently connected to one another. A permanent connection prevents the first and second fastening means from being inadvertently released during operation.

The predetermined minimum prestressing force is, for example, 1 N or 2 N or 5 N or 10 N. The prestressing force can also be less than a predetermined maximum prestressing force. The The maximum preload force is, for example, 100 N or 50 N or 10 N.

In one embodiment, the first fastening means has a recess with an internal thread, the second fastening means having a recess and a section of the second contact surface of the circuit board, wherein in the connected state a screw is screwed into the internal thread and is arranged in the recess of the second fastening means and rests against the section of the second contact surface of the circuit board, so that a clamping force acts between the screw and the section of the second contact surface, the clamping force being at least a part of the connecting force.

If the first fastening means has a recess with an internal thread and the second fastening means has a recess and a portion of the second contact surface of the circuit board, a screw can be inserted into the recess of the second fastening means and screwed into the internal thread. A detachable connection between the first fastening means and the second fastening means can be provided with the aid of the screw. When screwing the screw into the internal thread, the clamping force can be adjusted by selecting a specific tightening torque. By adjusting the clamping force, the connection force can be adjusted, in particular such that the connection force is greater than the predetermined minimum connection force.

Each recess mentioned in connection with the present invention can be a bore and / or an elongated hole. A hole can be made quickly and easily. An elongated hole enables an adjustable connection with which tolerances can be compensated.

In one embodiment, the first fastening means has a bolt section and a head connected to the bolt section with a contact surface, the second fastening means having a recess and a section of the second contact surface of the printed circuit board, the bolt section being arranged in the recess of the second fastening means in the connected state and the contact surface of the head and the section of the second contact surface of the circuit board rest against one another, so that a clamping force acts between the contact surface of the head and the section of the second contact surface of the circuit board, the clamping force being at least part of the connecting force.

If the first fastening means has a bolt section and a head connected to the bolt section with a contact surface and the second fastening means has a recess and a section of the second contact surface of the printed circuit board, a permanent connection can be provided between the first fastening means and the second fastening means. In addition, if the first fastening means has a bolt section and a head connected to the bolt section with a contact surface and the second fastening means has a recess and a section of the second contact surface of the circuit board, the first fastening means can have one before connecting the first fastening means to the second fastening means Have bolts with a distal head portion. A bolt with a distal head section can also be referred to as a pin. To connect the first and second fastening means to one another, the first fastening means and the second fastening means can be moved towards one another such that the bolt is brought into the recess. The first fastening means and the second fastening means can then be connected to one another in that the distal head section is plastically deformed in such a way that the head of the first fastening means is formed from the distal head section, so that the bolt section of the first fastening means is arranged in the recess and the head on the contact surface of the second fastening means rests. The plastic deformation of the distal head section, in which the head is formed from the distal head section, can also be referred to as hot caulking.

In one embodiment, the first fastening means has a latching lug with a contact surface and a spring element with a contact surface, the spring element being able to be brought from an unloaded state into an elastically pretensioned state, the second fastening means being a portion of the first Has the contact surface of the circuit board and a portion of the second contact surface of the circuit board, wherein in the connected state the contact surface of the spring element is in contact with the portion of the first contact surface, the contact surface of the latching nose is in contact with the portion of the second contact surface, and the spring element is in the pretensioned state, so that a clamping force acts between the contact surface of the spring element and the section of the first contact surface and between the contact surface of the locking lug and the section of the second contact surface, the clamping force being at least part of the connecting force.

If the first fastening means has a latching lug with a contact surface and a spring element with a contact surface and the second fastening means has a portion of the first contact surface of the circuit board and a portion of the second contact surface of the circuit board, a releasable connection can be provided between the first fastening means and the second fastening means will.

The spring element can be brought from the unloaded state into the elastically pretensioned state. In the elastically pretensioned state, the entire clamping force or at least part of the clamping force can be provided by the spring element. The spring element is preferably not deformed in the unloaded state. In the elastically pretensioned state, the spring element is preferably deformed in a linear-elastic manner. A linear-elastic deformation of the spring element in the elastically pretensioned state ensures that the spring element can be brought from the unloaded state into the elastically pretensioned state and back again from the elastically pretensioned state into the unloaded state. In the unloaded state, the spring element can assume its original shape without plastic deformation components influencing a future deformation behavior of the spring element. Furthermore, a linear-elastic deformation of the spring element in the elastically pretensioned state can enable a force effect emanating from the spring element to be maintained in the elastically pretensioned state over a long period of use of the sensor device.

If the first fastening means has a latching lug with a contact surface and a spring element with a contact surface and the second fastening means has a portion of the first contact surface of the circuit board and a portion of the second contact surface of the circuit board, the first fastening means and can be used to connect the first and second fastening means to one another the second fastening means are moved towards each other in such a way that the contact surface of the spring element rests against the first contact surface and the spring element is brought from the unloaded state to the elastically pretensioned state until the contact surface of the latching lug rests against the section of the second contact surface.

In one embodiment, the sensor device has an electrically insulating insulating element with a receiving surface and a contact surface, which run parallel to one another, wherein in the connected state the receiving surface of the insulating element forms a section of the channel and the contact surface of the insulating element lies flat against the first contact surface of the circuit board.

The insulating element is electrically insulating and thus provides electrical insulation between the printed circuit board and the section of the busbar when the section of the busbar is received in the channel. The receiving surface of the insulating element can form a section of the channel so that the section of the busbar can rest against the receiving surface of the insulating element. As a result of the section of the busbar resting against the receiving surface of the insulating element, a form fit between the section of the busbar and the receiving surface of the insulating element, in particular perpendicular to the channel plane, can be provided. The contact surface of the insulating element can lie flat against the first contact surface of the circuit board, so that the first contact surface of the circuit board can mechanically support the contact surface of the insulating element. In addition, the planar contact of the contact surface of the insulating element on the first contact surface of the circuit board enables the creepage distances of the circuit board to be lengthened on the side of the first contact surface. The insulating element can have a fastening means which can be connected to the first and / or the second fastening means. For example, the fastening means of the insulating element can be connected to the first and / or second fastening means in the connected state. The fastening means of the insulating element can be a recess, in particular a bore.

As already described, the base part can have a first fastening means, the circuit board a second fastening means and / or the insulating element can have a fastening means. However, the present invention is not limited to any single fastening means. Rather, the base part can have several first fastening means and / or the circuit board can have several second fastening means and / or the insulating element can have several fastening means. In one of these cases, the features, technical effects and / or advantages described in connection with one of the corresponding fastening means also apply at least in an analogous manner to each of the corresponding plurality of fastening means, so that a corresponding repetition is dispensed with at this point.

In one embodiment, the insulating element has a film. Foils can be manufactured with particularly small thickness tolerances, so that a distance perpendicular to the channel plane between the sensor and the busbar can be set particularly precisely with a foil.

In one embodiment, the base part forms the insulating element integrally. The integral formation of the insulating element by the base part enables the base part to have the insulating element, so that the receiving surface of the insulating element is a portion of the receiving surface of the Can form the base part. The receiving surface of the base part can form the entire channel so that, when the section of the busbar is received by the channel, the section of the busbar rests circumferentially on the receiving surface of the base part perpendicular to the direction of extension of the section of the busbar. Such a circumferential contact of the section of the busbar can be achieved, for example, if the base part is an injection-molded part. During the manufacture of the base part, the busbar can be encapsulated by the injection molding compound as an injection-molded part, so that the busbar is encapsulated by the base part designed as an injection-molded part.

In one embodiment, the base part forms a projection which extends into the channel, wherein, when the section of the busbar is arranged in the channel and has a recess, the projection of the base part engages in the recess of the busbar. The projection of the base part enables the busbar to be positioned with high accuracy in the channel if the busbar has the recess, the shape of which preferably corresponds to the shape of the projection. The projection and the recess are preferably designed such that a form fit is provided between the projection and the recess parallel to the channel plane, preferably in the direction of the extension direction of the section of the busbar.

In one embodiment, the base part has a first positioning means that extends perpendicular to the channel plane, the circuit board having a positioning means that extends perpendicular to the first contact surface of the circuit board, wherein in the connected state the positioning means of the base part is perpendicular to the first contact surface of the circuit board extends and engages in the positioning means of the circuit board. The extension of the positioning means of the base part perpendicular to the channel plane and the extension of the positioning means of the circuit board perpendicular to the first contact surface of the circuit board ensure a positive fit between the positioning means of the base part and the positioning means of the circuit board in a direction parallel to the channel plane when the sensor device is in the connected state and the positioning means of the base part engages in the positioning means of the circuit board. In addition, the extension of the positioning means of the base part perpendicular to the channel plane and the extension of the positioning means of the circuit board perpendicular to the first contact surface of the circuit board ensure a high level of positioning accuracy between the base part and the circuit board, so that the sensor connected to the circuit board is comparatively accurate to a busbar arranged in the channel can be positioned. The positioning means of the base part can be designed as a positioning pin. The positioning means of the circuit board can be designed as a recess, in particular as a bore or elongated hole.

In one embodiment, the insulating element has a positioning means, the positioning means of the base part engaging the positioning means of the insulating element in the connected state. The engagement of the positioning means of the base part in the positioning means of the insulating element ensures a high degree of positioning accuracy between the base part and the insulating element. The positioning means of the insulating element can extend perpendicular to the contact surface of the insulating element. An extension of the positioning means of the insulating element perpendicular to the contact surface of the insulating element ensures a form fit between the positioning means of the base part and the positioning means of the insulating element in a direction parallel to the channel plane when the sensor device is in the connected state and the positioning means of the base part engages in the positioning means of the insulating element. In addition, the extension of the positioning means of the insulating element perpendicular to the contact surface of the insulating element ensures a high level of positioning accuracy between the base part and the insulating element, so that the insulating element can be positioned comparatively precisely with respect to a busbar arranged in the channel. The positioning means of the insulating element can be designed as a recess, in particular as a bore or elongated hole.

In one embodiment, the base part has a second positioning means for coupling to a coupling element of a preassembly tool on the side of the channel plane facing away from the circuit board, the second positioning means extending perpendicular to the channel plane. The second positioning means of the base part can extend perpendicular to the channel plane and enable a form fit between the second positioning means and the coupling element in a direction parallel to the channel plane when the base part is coupled to the pre-assembly tool via the second positioning means and the coupling element. The form fit between the second positioning means and the coupling element ensures high positioning accuracy between the base part and the pre-assembly tool, so that the first fastening means of the base part and the second fastening means of the circuit board can be precisely connected to one another.

As already described, the base part can have a first positioning means and a second positioning means, the printed circuit board can have a positioning means and / or the insulating element can have a positioning means. However, the present invention is not limited in each case to a single corresponding positioning means. Rather, the base part can have several first positioning means and / or several second positioning means and / or the printed circuit board have several positioning means and / or the insulating element have several positioning means. In one of these cases, the features, technical effects and / or advantages described in connection with one of the corresponding positioning means also apply at least in an analogous manner to each of the corresponding multiple positioning means, so that a corresponding repetition is dispensed with at this point.

The sensor device for receiving a busbar is described here. However, the present invention is not limited to the inclusion of a single bus bar. Rather, the sensor device can be designed to accommodate a plurality of busbars. In this case, the base part can have several receiving surfaces. Each of the receiving surfaces can each form at least a section of a corresponding channel of a plurality of channels. Each of the channels can each be designed to receive a corresponding section of one of the busbars and each have a base that extends along a corresponding channel plane. In the connected state, the first contact surface can face the multiple channels, the second contact surface can face away from the multiple channels, and the channel planes can run parallel to the first contact surface. The features, technical effects and / or advantages described in connection with the busbar also apply at least in an analogous manner to each of the multiple busbars, so that a corresponding repetition is dispensed with at this point.

According to a second aspect of the invention, the aforementioned object is achieved by a base part with the features of claim 12. The base part is adapted to be connected to a circuit board in order to form a sensor device according to the first aspect. The base part has the receiving surface, which forms at least the section of the channel with the bottom, which extends along the channel plane, for receiving the section of the busbar. The base part has the first fastening means which can be connected to the second fastening means of the circuit board.

The features, technical effects and / or advantages described in connection with the sensor device according to the first aspect of the invention also apply at least in an analogous manner to the base part according to the second aspect of the invention, so that a corresponding repetition is dispensed with at this point.

According to a third aspect of the invention, the aforementioned object is achieved by a busbar sensor arrangement having the features of claim 13. The busbar sensor arrangement has a sensor device according to the first aspect and a busbar. The sensor device is in the connection state. A portion of the busbar is arranged in the channel.

The features, technical effects and / or advantages described in connection with the sensor device according to the first aspect of the invention also apply at least in an analogous manner to the busbar sensor arrangement according to the third aspect of the invention, so that a corresponding repetition is dispensed with at this point becomes.

In one embodiment, the section of the busbar protrudes perpendicular to the channel plane beyond the receiving surface of the base part. The protrusion of the section of the busbar perpendicular to the channel plane over the receiving surface of the base part allows that when the first and second fastening means are connected to one another and a connecting force acts perpendicular to the channel plane between the first and second fastening means, between the section of the busbar and the bottom of the Channel and between the section of the busbar and the first contact surface of the circuit board at least a part of the connecting force acts. An at least partially acting connecting force both between the conductor rail and the bottom of the channel and between the conductor rail and the first contact surface of the circuit board provides a force fit between the sensor device and the conductor rail. In the event that the sensor device has the insulating element, the protrusion of the section of the busbar perpendicular to the channel plane over the receiving surface of the base part enables that both between the busbar and the receiving surface of the insulating element and between the contact surface of the insulating element and the first contact surface of the circuit board At least part of the connecting force acts when the first and second fastening means are connected to one another and a connecting force acts perpendicular to the channel plane between the first and second fastening means. If at least a part of the connecting force acts on the section of the busbar, a force fit can be provided between the sensor device and the busbar. Such a frictional connection is particularly suitable for ensuring an exact positioning of the sensor relative to the section of the busbar even with high vibration loads. The busbar can be received in the channel in a form-fitting and force-fitting manner. The busbar sensor arrangement preferably has no further connection between the sensor device and the busbar.

In one embodiment, a gap is arranged between the base part and a section of the first contact surface of the circuit board. By arranging the gap between the base part and the section of the first contact surface of the circuit board, the connecting force between the first and second fastening means can be precisely adjusted. In particular in the event that the section of the busbar protrudes perpendicular to the channel plane over the receiving surface of the base part, at least the part of the connecting force that acts on the section of the busbar can be precisely adjusted with the aid of the gap. Due to the precise setting of the part of the connecting force that acts on the section of the busbar, the non-positive reception of the section of the busbar in the channel can be set precisely, so that an exact positioning of the sensor relative to the section of the busbar is ensured even with high vibration loads can.

In one embodiment, the section of the busbar has a recess, the projection of the base part engaging the recess of the busbar. The recess in the section of the busbar and the projection of the base part enable the busbar to be highly accurately positioned in the channel. The projection and the recess are preferably designed such that a form fit is provided between the projection and the recess parallel to the channel plane, preferably in the direction of the extension direction of the section of the busbar.

The busbar sensor arrangement can be designed as a pre-assembly assembly. The formation of the busbar sensor arrangement as a preassembly module enables the busbar sensor arrangement to be calibrated in the rest of the converter before it is installed. In particular, the formation of the busbar sensor arrangement as a pre-assembly assembly enables calibration at different temperatures prior to assembly. The formation of the busbar sensor arrangement as a pre-assembly assembly can thus provide a cycle time reduction in the final assembly line.

• 1 zeigt eine schematische Perspektivansicht einer ersten Ausführungsform einer erfindungsgemäßen Stromschienen-Sensor-Anordnung mit einer Sensorvorrichtung mit einem Basisteil.
• 2 zeigt eine schematische Explosionsansicht der ersten Ausführungsform der erfindungsgemäßen Stromschienen-Sensor-Anordnung in 1 von oben.
• 3 zeigt eine schematische Explosionsansicht der ersten Ausführungsform der erfindungsgemäßen Stromschienen-Sensor-Anordnung in 1 von unten.
• 4 zeigt eine schematische Perspektivansicht eines Schnitts (links) und eine schematische Schnittansicht des Schnitts (rechts) eines Ausschnitts einer zweiten Ausführungsform der erfindungsgemäßen Stromschienen-Sensor-Anordnung mit einer Sensorvorrichtung mit einem Basisteil.
• 5 zeigt eine schematische Perspektivansicht einer dritten Ausführungsform einer erfindungsgemäßen Stromschienen-Sensor-Anordnung mit einer Sensorvorrichtung mit einem Basisteil.
• 6 zeigt eine schematische Perspektivansicht eines Schnitts der dritten Ausführungsform der erfindungsgemäßen Stromschienen-Sensor-Anordnung in 5.

Further features, advantages and possible applications of the present invention emerge from the following description of the exemplary embodiments and the figures. All of the features described and / or shown in the figures, individually and in any combination, form the subject matter of the invention, regardless of their composition in the individual claims or their references. In the figures, the same reference symbols are also used for the same or similar objects.

• 1 shows a schematic perspective view of a first embodiment of a busbar sensor arrangement according to the invention with a sensor device with a base part.
• 2 FIG. 11 shows a schematic exploded view of the first embodiment of the busbar sensor arrangement according to the invention in FIG 1 from above.
• 3 FIG. 11 shows a schematic exploded view of the first embodiment of the busbar sensor arrangement according to the invention in FIG 1 from underneath.
• 4th shows a schematic perspective view of a section (left) and a schematic sectional view of the section (right) of a detail of a second embodiment of the busbar sensor arrangement according to the invention with a sensor device with a base part.
• 5 shows a schematic perspective view of a third embodiment of a busbar sensor arrangement according to the invention with a sensor device with a base part.
• 6th FIG. 10 shows a schematic perspective view of a section through the third embodiment of the busbar sensor arrangement according to the invention in FIG 5 .

1 shows a schematic perspective view of a first embodiment of a busbar sensor arrangement according to the invention 1 . The busbar sensor arrangement 1 has a sensor device 3 and a power rail 5 that as the first power rail 5 can be designated, and a second busbar 7th on. In 1 is the sensor device 3 in a connected state. A section of the first busbar 5 is arranged in a channel that can be referred to as the first channel. A section of the second busbar 7th is arranged in a second channel. The sensor device 3 takes the first busbar 5 and the second busbar 7th so on that the first power rail 5 and the second busbar 7th are spaced apart from one another in an electrically insulating manner.

The sensor device 3 has a base part 9 , an electrically insulating insulating element 11 , a flat printed circuit board 13 , a sensor 15th , a connector part 17th and screws 19th on.

The base part 9 has a receiving surface, which can be referred to as a first receiving surface, and a second receiving surface. The first receiving surface forms a section of the first channel for receiving the section of the first busbar 5 . The second receiving surface forms a portion of the second channel for receiving the portion of the second busbar 7th . The first channel has a floor, which can be referred to as the first floor and extends along a channel plane, which can be referred to as the first channel plane. The second channel has a second floor that extends along a second channel plane. The first channel level and the second channel level run in the same plane. The first channel and the second channel run parallel to one another.

The base part 9 has two first positioning means 21st on. The first positioning means 21st each extend perpendicular to the first channel plane. Any positioning means 21st is designed as a positioning pin. In addition, the base part 9 a cable attachment area 23 on that one floor area 25th and away from the floor area 25th extending thighs 27 has, between which one or more cables can be routed.

The connector part 17th is part of a plug connection for forwarding sensor signals from the sensor 15th can be provided. The connector part 17th is next to the sensor 15th with the circuit board 13 connected. The screws 19th ensure the in 1 shown connection state of the sensor device 3 .

2 shows a schematic exploded view of the first embodiment of the busbar sensor arrangement according to the invention 1 in 1 from above. Four first fasteners 29 of the base part 9 are shown. Any of the first fasteners 29 of the base part 9 has a recess with an internal thread.

The base part 9 forms two protrusions 31 , of which a first head start 31 extends into the first channel and a second protrusion extends 31 extends into the second channel. The section of the first busbar 5 has a recess 33 on and the section of the second busbar 7th has a recess 33 on. The first lead 31 reaches into the recess 33 the first busbar 5 one and the second protrusion 31 reaches into the recess 33 the second busbar 7th one.

The section of the first busbar 5 protrudes perpendicular to the first channel plane over the first receiving surface of the base part 9 out. The section of the second busbar 7th protrudes perpendicular to the second channel plane over the second receiving surface of the base part 9 out.

The insulating element 11 is a film that can also be called an insulating film. In 2 is from the insulating element 11 a contact surface 35 shown. The insulating element 11 has two positioning means 37 , which are designed as recesses, and four fastening means 38 on, which are designed as recesses. One of the two positioning means 37 is designed as a bore. The other of the two positioning means 37 is designed as a slot open on one side.

From the circuit board 13 is a second contact surface 39 shown. The sensor 15th is with the circuit board 13 on the side of the second contact surface 39 connected. The connector part 17th is also with the circuit board 13 on the side of the second contact surface 39 connected. The circuit board 13 has four second fasteners 41 on. Each of the four second fasteners 41 each has a recess and a section of the second contact surface 39 the circuit board 13 on. It also has the circuit board 13 two positioning means 43 on. Each of the two positioning means 43 is designed as a bore.

3 shows a schematic exploded view of the first embodiment of the busbar sensor arrangement according to the invention 1 in 1 from underneath. The base part 9 has two second positioning means 45 which are designed for coupling with a coupling element of a pre-assembly tool. Each of the two second positioning means 45 is on that of the circuit board 13 arranged facing away from the first channel plane and extends perpendicular to the channel plane. Each of the two second positioning means 45 is designed as a recess.

In 3 is a recording surface 47 of the insulating element 11 shown. The recording area 47 runs parallel to the contact surface 35 (please refer 2 ). Also shows 3 a first contact surface 49 the circuit board 13 . The first contact surface 49 runs parallel to the second contact surface 39 (please refer 2 ).

Any of the first fasteners 29 of the base part 9 can with a corresponding one of the second fastening means 41 the circuit board 13 get connected. As mentioned earlier, the sensor device is 3 in 1 in a connected state. Each of the first fastening means is in the connected state 29 with a corresponding one of the second fastening means 41 connected. Each of the four screws is in the connected state 19th screwed into a corresponding internal thread. In addition, each of the four screws is in the connected state 19th in a corresponding recess of a fastening means 38 of the insulating element 11 and in a corresponding recess of the second fastening means 41 arranged. Further, each of the four screws is in the connected state 19th on a corresponding section of the second contact surface 39 the circuit board 13 on. Between every screw 19th and the corresponding section of the second contact surface 39 acts a clamping force that is at least part of a Connection force is that acts perpendicular to the first channel plane and is greater than a predetermined minimum connection force.

In the in 1 The connection state shown is the first contact surface 49 facing the first channel and the second channel. The second contact surface 39 faces away from the first channel and from the second channel. Each of the first channel plane and second channel plane runs parallel to the first contact surface 49 . In the connected state, a portion forms the receiving surface 47 of the insulating element 11 a portion of the first channel and a portion of the receiving surface 47 of the insulating element 11 forms a section of the second channel. The contact surface is also located 35 of the insulating element 11 at the first contact surface 49 the circuit board 13 flat on.

Each of the positioning means 43 the circuit board 13 extends perpendicular to the first contact surface 49 the circuit board 13 and is designed as a recess. In the in 1 each of the first positioning means extends 21st of the base part 9 perpendicular to the first contact surface 49 the circuit board 13 and engages in a corresponding positioning means 43 the circuit board 13 one. In addition, each of the first positioning means engages in the connected state 21st of the base part 9 in a corresponding positioning means 37 of the insulating element 11 one.

In the connection state, between the base part 9 and a section of the first contact surface 49 the circuit board 13 be arranged a gap. A section of the insulating element can be in this gap 11 be arranged.

4th shows a schematic perspective view of a section (left) and a schematic sectional view of the section (right) of a detail of a second embodiment of the busbar sensor arrangement according to the invention 1 . The first fastener 29 has a locking lug 51 with a contact surface and a spring element 53 with a contact surface. The spring element 53 can go from an unloaded state to an in 4th shown elastically pretensioned state. The second attachment means 41 has a portion of the first contact surface 49 the circuit board 13 and a portion of the second contact surface 39 the circuit board 13 on. In the in 4th The connection state shown is the contact surface of the spring element 53 on the section of the first contact surface 49 on. In addition, the contact surface of the latch is in the connected state 51 on the section of the second contact surface 39 on. The spring element 53 is in the pretensioned state, so that a clamping force between the contact surface of the spring element 53 and the section of the first contact surface 49 and between the contact surface of the locking lug 51 and the section of the second contact surface 39 works. The clamping force is at least part of a connection force which acts perpendicular to the first channel plane and is greater than a predetermined minimum connection force.

The first fastener 29 the busbar sensor arrangement according to the invention 1 can have a bolt section and a head connected to the bolt section with a contact surface. The second attachment means 41 the busbar sensor arrangement according to the invention 1 can be a recess and a section of the second contact surface 39 the circuit board 13 exhibit. In the connected state, the bolt section is in the recess of the second fastening means for this case 41 arranged. The contact surface of the head and the section of the second contact surface 39 the circuit board 13 then rest against one another, so that a clamping force between the contact surface of the head and the section of the second contact surface 39 the circuit board 13 works. The clamping force is at least a part of the connecting force which acts perpendicular to the first channel plane and is greater than a predetermined minimum connecting force.

5 shows a schematic perspective view of a third embodiment of the busbar sensor arrangement according to the invention 1 and 6th shows a schematic perspective view of a section of the third embodiment of the busbar sensor arrangement according to the invention 1 in 5 . Each of the four first fasteners 29 each has a locking lug 51 with a contact surface and a spring element 53 with a contact surface. Each of the spring elements 53 is in an unloaded condition. The base part 9 forms the insulating element 11 integral. The base part 9 can by overmolding the first busbar 5 and the second busbar 7th are produced, with solidification of the base part 9 this expands so that between the base part 9 and the first busbar 5 and between the base part 9 and the second busbar 7th a positive connection is established.

It should also be noted that “having” does not exclude any other elements or steps and “a” or “an” does not exclude a plurality. It should also be pointed out that features that have been described with reference to one of the above exemplary embodiments can also be used in combination with other features of other exemplary embodiments described above. Reference signs in the claims are not to be regarded as a restriction.

List of reference symbols

1

Busbar sensor arrangement

3

Sensor device

5

first busbar

7th

second busbar

9

Base part

11

Insulating element

13

Circuit board

15th

sensor

17th

Connector part

19th

screw

21st

first positioning means of the base part

23

Cable attachment area

25th

Floor area

27

leg

29

first fastening means

31

head Start

33

Recess

35

Contact surface of the insulating element

37

Positioning means of the insulating element

38

Fastening means of the insulating element

39

second contact surface of the circuit board

41

second fastening means

43

Positioning means of the circuit board

45

second positioning means of the base part

47

Receiving surface of the insulating element

49

first contact surface of the circuit board

51

Locking lug

53

Spring element

Claims (16)

Sensor device (3) for receiving a busbar (5) with a base part (9) with a receiving surface which forms at least a section of a channel with a base which extends along a channel plane for receiving a section of the busbar (5), and a first fastening means (29), a flat circuit board (13) with a first and a second contact surface (49, 39), which run parallel to each other, and a second fastening means (41) and a sensor (15), which with the circuit board (13) on the side of the second Contact surface (39) is connected, wherein the first and second fastening means (29, 41) can be connected to one another, wherein the sensor device (3) is in a connected state when the first and second fastening means (29, 41) are connected to one another, wherein in the connected state the first contact surface (49) faces the channel, the second contact surface (39) faces away from the channel, the channel plane runs parallel to the first contact surface (49) and between the first and second fastening means (29, 41) a Connecting force acts perpendicular to the channel plane, the connecting force being greater than a predetermined minimum connecting force. Sensor device (3) after Claim 1 , wherein the first fastening means (29) has a recess with an internal thread, the second fastening means (41) having a recess and a portion of the second contact surface (39) of the circuit board (13), wherein in the connected state a screw (19) in the internal thread is screwed in, is arranged in the recess of the second fastening means (41) and rests against the section of the second contact surface (39) of the printed circuit board (13), so that a clamping force between the screw (19) and the section of the second contact surface (39 ) acts, the clamping force being at least part of the connecting force. Sensor device (3) after Claim 1 , wherein the first fastening means (29) has a bolt section and a head connected to the bolt section with a contact surface, the second fastening means (41) having a recess and a section of the second contact surface (39) of the circuit board (13), wherein in the Connection state the bolt section is arranged in the recess of the second fastening means (41) and the contact surface of the head and the section of the second contact surface (39) of the circuit board (13) rest against one another, so that a clamping force between the contact surface of the head and the section of the second contact surface (39) of the printed circuit board (13) acts, the clamping force being at least part of the connecting force. Sensor device (3) after Claim 1 , wherein the first fastening means (29) has a latching lug (51) with a contact surface and a spring element (53) with a contact surface, the spring element (53) being able to be brought from an unloaded state into an elastically pretensioned state, the second fastening means (41) has a section of the first contact surface (49) of the circuit board (13) and a section of the second contact surface (39) of the circuit board (13), wherein in the connected state the contact surface of the spring element (53) rests on the section of the first contact surface (49), the contact surface of the locking lug (51) rests on the section of the second contact surface (39), and the spring element (53) is in the pretensioned state so that a clamping force acts between the contact surface of the spring element (53) and the section of the first contact surface (49) and between the contact surface of the latching lug (51) and the section of the second contact surface (39), the clamping force being at least part of the connecting force is. Sensor device (3) according to one of the preceding claims, wherein the sensor device (3) has an electrically insulating insulating element (11) with a receiving surface (47) and a contact surface (35) which run parallel to one another, wherein in the connected state the receiving surface (47) of the insulating element (11) forms a section of the channel and the contact surface (35) of the insulating element (11) lies flat against the first contact surface (49) of the circuit board (13). Sensor device (3) after Claim 5 , wherein the insulating element (11) comprises a film. Sensor device (3) after Claim 5 wherein the base part (9) integrally forms the insulating element (11). Sensor device (3) according to one of the preceding claims, wherein the base part (9) forms a projection (31) which extends into the channel, wherein when the section of the busbar (5) is arranged in the channel and a recess (33 ), the projection (31) of the base part (9) engages in the recess (33) of the busbar (5). Sensor device (3) according to one of the preceding claims, wherein the base part (9) has a first positioning means (21) which extends perpendicular to the channel plane, wherein the circuit board (13) has a positioning means (43) which extends perpendicular to the first contact surface (49) of the circuit board (13), wherein in the connected state the first positioning means (21) of the base part (9) extends perpendicular to the first contact surface (49) of the circuit board (13) and engages in the positioning means (43) of the circuit board (13). Sensor device (3) after Claim 9 wherein the insulating element (11) has a positioning means (37), wherein in the connected state the first positioning means (21) of the base part (9) engages in the positioning means (37) of the insulating element (11). Sensor device (3) according to one of the preceding claims, wherein the base part (9) has a second positioning means (45) for coupling to a coupling element of a pre-assembly tool on the side of the channel plane facing away from the printed circuit board (13), wherein the second positioning means (45) extends perpendicular to the channel plane. Base part (9) which is adapted to be connected to a printed circuit board (13) to provide a sensor device (3) according to one of the Claims 1 to 11 to form, wherein the base part (9) has the receiving surface which forms at least the portion of the channel with the bottom, which extends along the channel plane, for receiving the portion of the busbar (5), the base part (9) the first fastening means (29) which can be connected to the second fastening means (41) of the circuit board (13). Busbar sensor arrangement (1) with a sensor device (3) according to one of the Claims 1 to 11 and a busbar (5), wherein the sensor device (3) is in the connected state and a portion of the busbar (5) is arranged in the channel. Busbar sensor arrangement (1) Claim 13 , wherein the section of the busbar (5) protrudes perpendicular to the channel plane over the receiving surface of the base part (9). Busbar sensor arrangement (1) according to one of the Claims 13 and 14th , a gap being arranged between the base part (9) and a section of the first contact surface (49) of the circuit board (13). Busbar sensor arrangement (1) according to one of the Claims 13 to 15th , wherein the section of the busbar (5) has a recess (33), the projection (31) of the base part (9) engaging in the recess (33) of the busbar (5).

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