WO2024099652A1 - Contacting unit for an electric motor - Google Patents

Abstract

The invention relates to a contacting unit for an electric motor. The contacting unit can be arranged between two contact surfaces of a stator housing of the electric motor and of an electronics housing having electronics for controlling the electric motor, said contact surfaces facing each other. The contacting unit comprises a main body and at least a first elastically deformable spring element. The main body is designed such that, when arranged between the two contact surfaces, said main body is spaced apart at least from a first of the two contact surfaces and, in said arrangement, the first spring element extends from the main body toward the first contact surface. The first spring element is designed such that, in said arrangement, at least in a deformed state of the first spring element, the first spring element can be brought into contact with the first contact surface and presses the main body toward the second contact surface. The contacting unit is designed to provide an electrical connection between the two contact surfaces.

Description

Contact unit for an electric motor

The present invention relates to a contacting unit for an electric motor, an electric motor and a vehicle, in particular a vehicle driven by an electric motor with such a contacting unit and/or such an electric motor.

An electric motor, for example a permanently excited synchronous machine, PSM of a vehicle, can comprise a stator housing and a rotor arranged in the stator housing. To control the electric motor, an electronics housing with electronics can be arranged on the stator housing, with the control being carried out by means of the electronics.

A time-varying magnetic field induces a vortex-shaped electric field around magnetic flux lines in the stator housing. This electric field drives ring-shaped currents through the stator housing, so-called eddy currents. These flow better the higher the frequency of the magnetic field and the conductivity of the stator housing. According to the law of magnetic flux, the eddy currents generate a magnetic field, the so-called reaction field. Inside the vortex, this is directed opposite to the external magnetic field and weakens it. As the frequency increases, the induction becomes stronger because the change in the magnetic flux becomes greater. Even a small area penetrated by the magnetic field is enough to generate sufficient eddy currents. The current density increases towards the edge of the stator housing, as does the magnetic field strength, which is made up of the external field and the reaction field. This process is called current displacement. At a sufficiently high frequency, the current only flows over the outer circumference of the stator housing (skin effect) and an electrodynamic shield is formed.

Openings in this shield are caused by ventilation openings and housing joints without seals, among other things, which leads to a reduced shielding effect. Since the current induced by the alternating field can no longer flow unhindered, slot antennas can form. Due to the design, continuous contact between the stator housing and the electronics housing cannot be guaranteed, so that cavities or air resistance are present between the stator housing and the electronics housing. This air resistance can also lead to the disadvantages described above.

It is therefore an object of the present invention to provide a contacting unit, an electric motor and a vehicle which eliminate and/or at least improve one or more of the aforementioned disadvantages. In particular, it is an object of the present invention to provide an easy-to-arrange and efficient unit which eliminates and/or at least improves the aforementioned disadvantages.

The object is achieved according to a first aspect by a contacting unit for an electric motor, wherein the contacting unit can be arranged between two mutually facing contact surfaces of the electric motor, in particular a stator housing of the electric motor and an electronics housing with electronics for controlling the electric motor. The contacting unit comprises a base body and at least a first elastically deformable spring element, wherein the base body is designed such that, in a state arranged between the two contact surfaces, it is or can be spaced apart from at least a first of the two contact surfaces, and the first spring element extends or can be extended from the base body in the direction of the first contact surface in the state of the base body arranged between the two contact surfaces, in particular in an arranged state of the electronics housing on the stator housing. The first spring element is further designed, in the state of the base body arranged between the two contact surfaces, to be contactable with the first contact surface in a deformed state of the first spring element, in particular to be in contact with the first contact surface, and to press the base body in the direction of the second contact surface, wherein the contacting unit is designed to provide an electrically conductive connection between the two contact surfaces in the state of the base body arranged between the two contact surfaces. The proposed contacting unit can be arranged and/or positioned on a corresponding contact surface of the stator housing before the electronics housing is arranged on and/or on the stator housing. For example, the base body can rest on the (second) contact surface of the stator housing. The at least one first spring element can extend away from the base body in such a way that when the electronics housing is arranged on the stator housing, the spring element is bent and/or bendable. The first spring element is in contact with the (first) contact surface of the electronics housing and the contacting unit represents an electrically conductive connection between the two contact surfaces. The contacting unit can consist of metal and/or one or more electrically conductive materials. Such a material can be or comprise high-strength stainless steel. The contacting unit can be coated to conduct currents, in particular with nickel. In particular, the contacting unit can consist of a metal and/or one or more electrically conductive materials that have a low electrical resistance. Accordingly, a low alternating resistance can be provided between the stator housing and the electronics housing and the current lines can be guided via the contacting unit.

The electric motor can be a permanently excited synchronous machine, PSM, a three-phase asynchronous machine, ASM, a permanent magnet synchronous motor, PMSM or a similar electric machine which has a stator housing and a rotor, wherein a torque is generated by a power supply to the electric machine by means of the stator housing and the rotor.

The electronics of the electronics housing can include and/or be power electronics for controlling the electric motor.

The first spring element can be designed to change from an original state to the deformed state in the state of the base body arranged between the two contact surfaces. In particular, the first and/or a subsequent second spring element can change from the original state to the deformed state when the electronics housing is placed on the stator housing.

The first spring element is elastically deformable. The first spring element and/or each further spring element described (first and/or second spring element(s)) are designed in such a way that they have elasticity, wherein the elasticity, in particular through a suitable choice of the material of the spring elements, enables switching between the original state and the deformed state. The two contact surfaces of the stator housing and electronics housing can have a predetermined distance between them when the electronics housing is arranged on the stator housing. This predetermined distance can be due to the design. The electronics housing can be attached to the stator housing using screws, for example. The electronics housing can be arranged on the stator housing in such a way that a weight force of the electronics housing already ensures that the electronics housing rests on the stator housing. In addition, a position of the electronics housing can be secured using the screws and/or an additional contact force for pressing the electronics housing onto the stator housing can be used. Accordingly, a weight force of the electronics housing and/or the contact force can act on the spring element(s) between the two contact surfaces of the stator housing and the electronics housing, whereby the spring element(s) are deformed and change from the original state (rest state) to the deformed state. The elasticity can be selected such that the spring elements are at least elastic enough to be able to bend based on this predetermined distance, in particular without breaking and/or being damaged. Consequently, the elasticity can be determined based on this predetermined distance.

The contacting unit can further comprise at least one second elastically deformable spring element, which extends or can be extended from the base body in the direction of the second contact surface, in particular when the base body is arranged between the two contact surfaces. The second spring element can be designed to arranged state of the base body from an original state to a deformed state, wherein the second spring element can be designed to be in contact with the second contact surface in the deformed state and to press the base body in the direction of the first contact surface. The base body can in particular be designed such that it is spaced apart from the two contact surfaces, advantageously in the arranged state of the electronics housing on the stator housing.

The contacting unit can comprise two, three or more elastically deformable first and/or second spring elements. Features described above and below relating to the first and second spring elements can be applied to any of the plurality of first and second spring elements described above or below.

The at least one first spring element or the two, three or more first spring elements can be designed to be in contact with the first contact surface in the deformed state, in particular in the state of the base body arranged between the two contact surfaces, and to press the base body in the direction of the second contact surface such that the base body is in contact with the second contact surface. If the contacting unit is designed without second spring elements, the first spring elements can be used to press the base body onto the second contact surface and provide an electrically conductive connection.

When the contacting unit is designed with first and second spring elements, the at least one first and the at least one second spring element can extend to the first and the second contact surface, in particular when the base body is arranged between the two contact surfaces. In this case, the base body can be spaced apart from both contact surfaces and/or can be arranged between the two contact surfaces, since the at least one first spring element pushes the base body away from the first contact surface and the second spring element pushes the base body away from the second contact surface. By providing the first and second spring elements, an improved adaptation of the contacting unit to the two contact surfaces can be achieved.

A distal end section of at least one of the first and/or second spring elements can have an original distance from the base body in the original state and a deformation distance from the base body in the deformed state, wherein the deformation distance is smaller than the original distance. The original distance can in particular be greater than the distance between the two contact surfaces. Accordingly, it can be ensured that the contacting unit comes into contact with both contact surfaces in the state of the base body arranged between the two contact surfaces. The original distance and the deformation distance can extend along a thickness direction defined below.

At least one of the first and/or second spring elements, in particular a proximal end section of the respective spring element, can be arcuate at least in sections and/or have a longitudinal section extending along an extension direction of the respective spring element. In particular, in a one-piece design of the contacting unit, at least one of the first and/or second spring elements, starting from the base body, can initially have an arcuate section, followed by the longitudinal section and followed by a further arcuate section. The longitudinal section can be straight. At least one of the first and/or second spring elements can be hook-shaped.

At least one of the first and/or second spring elements can be formed by means of a recess on the base body. The contacting unit can initially be provided as a sheet metal in a manufacturing process, wherein the at least one first and/or second spring element is punched out on at least one side of the sheet metal by means of a punching process. The respective spring element initially extends parallel to the sheet metal or the base body. In a further step, the respective spring element can be deformed, in particular bent, in such a way that it extends away from the base body. With other In other words, the spring element extends in a direction of extension that is not in the plane of the base body. The recess can in particular be larger than the respective spring element, so that deformation or bending can be carried out more easily.

The base body can extend from a first end section to a second end section along a longitudinal direction and the base body can have a predetermined base body thickness along a thickness direction that runs perpendicular to the longitudinal direction. The two contact surfaces can be formed parallel to one another. Furthermore, the longitudinal direction can be formed parallel to at least one of the contact surfaces. The base body thickness can be 0.01 to 0.5, in particular 0.01 to 0.3, advantageously 0.02 to 0.2 mm. The at least one first and/or second spring element can have a spring element thickness that is equal to the base body thickness. The base body can extend along a width direction that runs orthogonal to the longitudinal direction and the thickness direction with a predetermined width, wherein in particular the base body thickness is smaller than the width. The at least one first and/or second spring element can extend along an extension direction that extends essentially within a plane that is spanned by the longitudinal direction and the thickness direction. The thickness, in particular along the thickness direction, of the respective spring element is perpendicular to that of this plane. A width, in particular along the width direction of at least one of the spring elements can extend within the width direction, wherein the thickness of the at least one spring element is smaller than the width of the base body.

At least one of the first and/or second spring elements can be adjacent and/or arranged on a first side of the base body. Alternatively or additionally, at least one of the first and/or second spring elements can be adjacent and/or formed on a second side of the base body, wherein the base body extends in the width direction from the first side to the second side. Adjacent can mean that the spring elements are formed on an edge of the base body. Consequently, at least one first and/or second spring element can be on the first side and at least one first and/or second Spring element may be adjacent on the second side, wherein, viewed in the width direction, the base body is formed and/or arranged between the spring elements.

At least one of the first and at least one of the second spring elements can be adjacent to one of the first and/or second sides, such that the first and second spring elements are alternately adjacent along the respective side along the first and/or second side. This alternating arrangement can improve the stability of the contacting unit, in particular such that it does not slip when the base body is arranged between the two contact surfaces. Along the respective side, the first and/or second spring elements can have a regular and/or irregular distance from at least one adjacent spring element along this side. It can be advantageous to arrange several spring elements with a first, in particular short, distance in areas in which strong current lines could be formed and/or the alternating current resistance between the stator housing and the electronics housing should be particularly low, and to arrange one or more spring elements with a second, in particular larger distance in areas in which weaker current lines are formed and/or the alternating current resistance can be somewhat higher compared to the previous areas.

At least one of the first spring elements can be adjacent to one of the two sides and at least one of the second spring elements can be adjacent to the other of the two sides such that they are alternately adjacent along the longitudinal direction when viewed along the width direction. This can further improve the stability of the contacting unit.

The base body can be straight and/or curved and/or arched between the first and second end sections.

The base body can be ring-shaped and/or racetrack-shaped. Alternatively or additionally, the contacting unit can be formed in one piece. In the ring-shaped and/or racetrack-shaped design of the base body or the Contacting unit, the two end sections can be connected to one another in order to form a closed ring-shaped and/or racetrack-shaped form of the contacting unit. The ring-shaped form can be a circular form. The racetrack-shaped form can be formed from two straight sections and two semicircular sections of the base body, wherein the two straight sections connect to opposite end sections of the semicircular sections. The contacting unit can have a form that extends substantially within the space formed between the two contact surfaces.

At least one of the first and/or second spring elements can be adjacent to an inner circumferential side of an inner circumference of the base body and/or at least one of the first and/or second spring elements can be adjacent to an outer circumferential side of an outer circumference of the base body. The base body can extend along the width direction from the inner circumferential side to the outer circumferential side. The inner circumferential side and the outer circumferential side can be the first and second sides.

The contacting unit, in particular the base body, can be designed in sheet metal form.

The contacting unit, in particular the base body and the at least one first and/or second spring element or the spring elements can be designed to be electrically conductive.

The two, three or more first spring elements can be adjacent and/or arranged along the respective side of the base body with a regular and/or irregular distance from one another. Alternatively or additionally, the two, three or more second spring elements can be adjacent and/or arranged along the respective side of the base body with a regular and/or irregular distance from one another. The at least one first spring element extends in the direction of the first contact surface. The at least one first spring element can extend further in the direction of the longitudinal direction or counter to the direction of the longitudinal direction. The at least one second spring element can extend in the direction of the second contact surface. The at least one second spring element can extend further in the direction of the longitudinal direction or counter to the direction of the longitudinal direction. If the contacting unit is viewed along the width direction, the first and/or second spring elements can therefore be formed in the direction of the longitudinal direction and/or counter to the longitudinal direction.

The contacting unit can further comprise at least one first fastening unit and/or at least one second fastening unit and the at least one first fastening unit can be adjacent and/or arranged on the first side and the at least one second fastening unit can be adjacent and/or arranged on the second side, wherein the at least one first and/or second fastening unit can be designed to arrange and/or fasten the contacting unit, in particular the base body, by clamping the respective fastening unit between the stator housing and the electronics housing.

The at least one first and/or second fastening unit can be designed in the form of a retaining lug. The fastening unit can also be electrically conductive. The first and/or second fastening unit can be adjacent to the first and/or second side. Furthermore, the first and/or second fastening unit can extend substantially along the longitudinal direction and the thickness direction. The first and/or second fastening unit can have a predetermined angle to the base body. The predetermined angle can in particular be a right angle.

Furthermore, the at least one first and/or second fastening unit can be designed such that it is clamped between third and fourth contact surfaces of the stator housing and the electronics housing, wherein the third and fourth contact surfaces are different from the first and second contact surfaces. In particular, one of the first and second contact surfaces, in particular the second contact surface, can be adjacent to the third contact surface.

The at least one first and/or second fastening unit can be designed to be received in a recess and/or notch of the respective third and/or fourth contact surface.

The object is achieved according to a second aspect by an electric motor comprising a contacting unit according to the first aspect.

The object is achieved according to a third aspect by a vehicle comprising a contacting unit according to the first aspect and/or an electric motor according to the second aspect.

The vehicle can be a vehicle that is powered by an electric motor. In particular, the vehicle can be an electric vehicle. The vehicle can be a car or a bus.

Preferred embodiments are explained using the accompanying figures. They show:

Fig. 1 is a perspective view of a first embodiment of a contacting unit;

Fig. 2 is a side view of the contacting unit;

Fig. 3 between a stator housing of an electric motor and a

Contacting unit arranged in the electronics housing according to the first embodiment;

Fig. 4 is a perspective view of a section of Fig. 4;

Fig. 5 is a side view of the contacting unit of Fig. 4;

Fig. 6 is a plan view of the contacting unit of Fig. 4;

Fig. 7 is a plan view of a contacting unit according to a second

embodiment; Fig. 8 is a perspective view of a third embodiment of a contacting unit;

Fig. 9 between a stator housing of an electric motor and a

Contacting unit arranged in the electronics housing according to the third embodiment;

Fig. 10 a vehicle with a contact unit.

In the figures, identical or essentially functionally identical or similar elements are designated by the same reference numerals. The proportions shown in the figures serve primarily to facilitate understanding of the invention and do not restrict the invention to these.

Fig. 1 shows a perspective view of a contacting unit 100 according to a first embodiment with a base body 110 and several first spring elements 120, 120'. The contacting unit 100 is designed in the shape of a racetrack and essentially has two straight sections, which extend from bottom left to top right in Fig. 1, and two arcuate, in particular semicircular sections, which form a left and a right section of the contacting unit 100 in Fig. 1. The contacting unit 100 is designed in one piece and is electrically conductive.

According to Fig. 1, the first spring elements 120, 120' are formed by means of recesses 111 of the base body 110. The contacting unit 100 also has an inner circumference with an inner circumference side S1 and an outer circumference with an outer circumference side S2, wherein the inner circumference side is a first side S1 and the outer circumference side is a second side S2. The first spring elements 120, 120' border on the second side S2. Consequently, the first spring elements 120, 120 are formed on an edge of the base body 110. The recesses 111 can have an inner contour that corresponds to and/or is modeled on an outer contour of the first spring elements 120, 120'. According to Fig. 1, the recesses 111 are designed in such a way that when the spring elements 120, 120' are bent into the plane of the base body 110, there would be no contact between the spring elements 120, 120' and the base body 110. Furthermore, the Base body 110 must be at least partially spaced from the first spring elements 120, 120'.

In Fig. 1, the spring elements 120, 120' extend upwards from the base body 110 in the direction of the image. The spring elements 120, 120' are at least partially curved at their proximal end sections on the base body. A distal end section of the spring elements 120, 120' is also curved. The proximal and distal end sections are connected to one another by means of a straight (middle) section.

If the contacting unit 100 is viewed from one of the sides S1 or S2, the base body 110 extends along a longitudinal direction LR and has a base body thickness along a thickness direction SR that runs perpendicular to the longitudinal direction LR (see Fig. 2). The spring elements 120 extend from the base body 110 upwards and in the direction of the longitudinal direction LR, while the spring elements 120' extend from the base body 110 upwards and against the direction of the longitudinal direction LR.

According to Fig. 1, a left half of the contacting unit 100 has the spring elements 120', while a right half of the contacting unit 110 has the spring elements 120. The invention is not limited to this arrangement. A first predetermined number of spring elements 120, 120' can alternately adjoin along the side S2. Alternatively or additionally, a second predetermined number of spring elements 120 can adjoin in series along the side S2. Additionally or alternatively, a third predetermined number of spring elements 120' can adjoin in series along the side S2.

The spring elements 120, 120', as well as all other spring elements 140, 140' described below are elastic. According to Fig. 1, the spring elements 120, 120' are in a resting state and have an original distance from the base body 110 along the direction of the thickness. If the spring elements 120, 120' are pressed downwards in the direction of the base body 110 by an electronics housing 202 shown below, the spring elements 120, 120' from the original state to a deformed state. In the deformed state, the spring elements 120, 120' have a deformation distance that is smaller than the original distance.

Fig. 2 shows the contacting unit 100 viewed along the width direction BR. In Fig. 2, the spring element 120, starting from the base body 110, first has the arcuate section, then the straight section and finally the further distal arcuate section. The distal arcuate section is designed such that an end section thereof points in the direction of the base body 110. If the spring element 120' is deformed, tilting with the contact surface resting on it, such as the contact surface of the electronics housing, can be prevented due to the arcuate distal end section.

Fig. 3 shows a stator housing 201 of an electric motor 310, wherein the stator housing 201 according to Fig. 3 has an inverted stator housing collar (designed downwards in Fig. 3). An electronics housing 202 is also shown, which is arranged on the stator housing 201 by means of screws 204. Furthermore, seals 203 are arranged between the electronics housing 202 and the stator housing 201. The electronics housing 202 comprises electronics, in particular power electronics for controlling the electric motor 310. The electronics housing 202 also has a housing collar, which is inserted into the stator housing collar. The housing collar surrounds a filter housing, in particular an AC filter housing 205 and a busbar, in particular a UVW busbar 206. The AC filter housing 205 is connected to the electronics housing 202 by means of seals 207.

According to Fig. 3, a contact surface of the housing collar is spaced apart from a contact surface of the stator housing collar. This can be due to the construction, for example due to the seal 203. Consequently, the two contact surfaces are spaced apart from one another and a resistance in the form of an air cavity is formed. This spacing increases an alternating current resistance between the electronics housing 202 and the stator housing 201, which, as mentioned at the beginning, is disadvantageous. As shown in Fig. 3, the stator housing 201 is designed such that it forms the stator housing collar in order to form a support surface for the contacting unit 100.

Alternatively or additionally, a structural gap or a distance can occur between the stator housing 201 and the electronics housing 202 in the area of the seals 203. In an embodiment not shown, the seals 203 can be dispensed with and the contact unit 100 can be arranged there between the stator housing 201 and the electronics housing 202 in order to provide an electrical contact between them. The contact unit 100 can be arranged between two opposite contact surfaces of the stator housing 201 and the electronics housing 202 in order to provide an electrical connection.

To reduce the alternating current resistance and to improve the guidance of current lines, the contacting unit 100 is arranged between the two contact surfaces. According to Fig. 3, the base body 110 is shown resting on the contact surface of the stator housing collar, while the spring elements 120' extend in the direction of the contact surface of the housing collar and are in contact with it. Due to the deformation of the spring elements 120' and a contact force resulting from the electronics housing 202, the base body 110 is pressed in the direction of the contact surface of the stator housing collar, in particular onto it. Accordingly, an electrically conductive connection is provided between the two contact surfaces.

Fig. 4 shows a perspective section of Fig. 3, from which it can be seen that the base body 110 is pressed onto the contact surface of the stator housing collar and the spring elements 120' are in contact with the contact surface of the housing collar. The spring elements shown are provided with the reference number 120' by way of example, whereby spring elements 120 can be provided additionally or alternatively.

Fig. 5 shows the contact unit 100 in the deformed state. The spring element 120' can be designed and deformed such that the distal End section at least partially immersed in a plane of the base body 110. The distal end section can be in contact with the base body 110 and/or spaced apart from it by suitable selection of the recess 111.

Fig. 6 shows a top view of the contacting unit 100 along the thickness direction SR. As can be seen from Fig. 6, the contacting unit 100 has the shape of a racetrack. In particular, the contacting unit 100 can be designed in such a way that a shape of the housing collar, in particular of the AC filter housing 205, is modeled. In other words, an inner contour of the contacting unit 100 can correspond to an outer contour of the housing collar, in particular of the AC filter housing 5. The contacting unit 100, in particular one of the base body 110 and/or the spring elements 120, 120', can be in contact with the AC filter housing 205 and/or spaced apart from it.

Fig. 7 shows a top view of a contacting unit 100' according to a second embodiment. According to Fig. 7, spring elements 120' border on the first side S1 and spring elements 120 and on the second side S2. Fig. 7 shows the top view along the thickness direction SR.

Viewed along the width direction BR, the contacting unit 100' can have spring elements 120, 120' alternating along the sides S1, S2. In other words, along the longitudinal direction LR, a spring element 120 on the side S2 is followed by a spring element 120' on the side S1, in turn followed by a spring element 120 on the side S1.

Fig. 8 shows a third embodiment of a contacting unit 100", wherein the contacting unit 100" has spring elements 140, 140' in contrast to the previous contacting units 100, 100'. The spring elements 140, 140' differ from the spring elements 120, 120' in that they extend downwards in the image plane. A contacting unit can have one or more of the spring elements 120, 120', 140, 140'. Furthermore, Fig. 8 shows the contacting unit 100" with fastening units 150. The fastening units extend downwards from the base body 110 in the image plane. Alternatively or additionally, fastening units 150 can extend upwards in the image plane. In other words, the fastening units 150 can extend along a contact surface of the electronics housing 202, in particular the housing collar and/or the stator housing 201, stator collar, when the base body 110 is arranged between the two contact surfaces. The fastening units 150 are designed such that the contacting unit 100", in particular the base body 110, is arranged between the stator housing 201 and the electronics housing 202 by clamping the respective fastening unit 150.

As shown in Fig. 9, the fastening elements 150 can be arranged between a contact surface of the housing collar, in particular the AC filter housing 205, and a contact surface of the stator housing 201, wherein they are clamped between these two contact surfaces. This can improve the position of the contacting unit 100" and prevent subsequent slipping. Furthermore, Fig. 9 shows that the base body 110 is in contact with the contact surface of the housing collar and the spring elements 140, 140' are in contact with the contact surface of the stator housing collar.

Fig. 10 shows a vehicle, in particular a vehicle driven by means of the electronic motor 310, with an electronic housing 202 and a contacting unit 100 according to one of the previous embodiments. By means of the contacting unit 100, an alternating current resistance between a stator housing of the electronic motor 310 and the electronic housing can be reduced, resulting in a reduced, in particular no formation of a slot antenna. Reference symbols

100, 100‘, 100“ contact unit

110 Basic body

111 Recess

120, 120' first spring elements

140, 140' second spring elements

150 Mounting unit

SR Strength Direction

LR longitudinal direction

BR latitude direction

S1 first page

S2 second page

201 Stator housing

202 Electronic housing

203 Seal

204 Screw

205 Filter housing

206 Busbar

207 Seal

300 vehicle

310 Electric Motor

Claims

Patent claims

1. Contacting unit (100, 100', 100") for an electric motor (310), wherein the contacting unit (100, 100', 100") can be arranged between two mutually facing contact surfaces of the electric motor (310), in particular a stator housing (201) of the electric motor (310) and an electronics housing (202) with electronics for controlling the electric motor (310), wherein the contacting unit (100, 100', 100") comprises a base body (110) and at least one first elastically deformable spring element (120, 120', 140, 140'), wherein the base body (110) is designed such that, in a state arranged between the two contact surfaces, it is spaced apart from at least a first of the two contact surfaces, and the first spring element (120, 120') in the arranged state of the base body (110) extends in the direction of the first contact surface, wherein the first spring element (120, 120') in the arranged state is designed to be contactable with the first contact surface at least in a deformed state of the first spring element (120, 120') and to press the base body (110) in the direction of the second contact surface, wherein the contacting unit (100, 100', 100") is designed to provide an electrically conductive connection between the two contact surfaces.

2. Contacting unit (100, 100', 100") according to claim 1, wherein the contacting unit (100, 100', 100") further comprises at least one second elastically deformable spring element (140, 140') which, in the arranged state, extends from the base body (110) in the direction of the second contact surface, wherein the second spring element (140, 140') in the arranged state is designed to be contactable with the second contact surface at least in a deformed state of the second spring element (140, 140') and to press the base body (110) in the direction of the first contact surface, wherein the base body (110) is designed in particular such that it is spaced apart from the two contact surfaces.

3. Contacting unit (100, 100', 100") according to claim 1 or 2, wherein the contacting unit (100, 100', 100") comprises two, three or more elastically deformable first and/or second spring elements (120, 120', 140, 140').

4. Contacting unit (100, 100', 100") according to one of the preceding claims, wherein a distal end portion of at least one of the first and/or second spring elements (120, 120', 140, 140') in an original state has an original distance from the base body (110) and in the deformed state has a deformation distance from the base body (110), wherein the deformation distance is smaller than the original distance.

5. Contacting unit (100, 100', 100") according to one of the preceding claims, wherein at least one of the first and/or second spring elements (120, 120', 140, 140'), in particular a proximal end section of the respective spring element (120, 120', 140, 140'), is at least partially arcuate and/or has a longitudinal section extending along an extension direction of the respective spring element (120, 120', 140, 140').

6. Contacting unit (100, 100', 100") according to one of the preceding claims, wherein at least one of the first and/or second spring elements (120, 120', 140, 140') is formed by means of a recess on the base body (1 10).

7. Contacting unit (100, 100', 100") according to one of the preceding claims, wherein the base body (1 10) extends from a first end portion to a second end portion along a longitudinal direction (LR) and the base body (1 10) has a predetermined base body thickness along a thickness direction (SR) which runs perpendicular to the longitudinal direction (LR), wherein the base body (110) extends along a width direction (BR) orthogonal to the longitudinal direction (LR) and to the thickness direction (SR) with a predetermined width, wherein in particular the base body thickness is smaller than the width.

8. Contacting unit (100, 100', 100") according to claim 7, wherein at least one of the first and/or second spring elements (120, 120', 140, 140') is adjacent to a first side (S1) of the base body (110), and/or wherein at least one of the first and/or second spring elements (120, 120', 140, 140') is adjacent to a second side (S2) of the base body (110), wherein the base body (110) extends in the width direction (BR) from the first side (S1) to the second side (S2).

9. Contacting unit (100, 100', 100") according to claim 8, wherein at least one of the first and at least one of the second spring elements (120, 120', 140, 140') are adjacent to one of the first and/or second sides (S1, S2), such that the first and second spring elements (120, 120', 140, 140') are adjacent along the first and/or second side (S1, S2) alternately along the respective side (S1, S2).

10. Contacting unit (100, 100', 100") according to claim 8 or 9, wherein at least one of the first spring elements (120, 120') is adjacent to one of the two sides (S1, S2) and at least one of the second spring elements (140, 140') is adjacent to the other of the two sides (S1, S2), such that, viewed along the width direction (BR), they are alternately adjacent along the longitudinal direction (LR).

11. Contacting unit (100, 100', 100") according to one of claims 7 to 10, wherein the base body (110) is straight and/or arcuate between the first and the second end portion.

12. Contacting unit (100, 100', 100") according to one of the preceding claims, wherein the base body (1 10) is ring-shaped and/or racetrack-shaped, and/or wherein the contacting unit (100, 100', 100") is integrally formed.

13. Contacting unit (100, 100', 100") according to claim 12, wherein at least one of the first and/or second spring elements (120, 120', 140, 140') is adjacent to an inner peripheral side of an inner periphery of the base body (110) and at least one of the first and/or second spring elements (120, 120', 140, 140') is adjacent to an outer peripheral side of an outer periphery of the base body (110).

14. Contacting unit (100, 100', 100") according to one of claims 8 to 13, wherein the contacting unit (100, 100', 100") further comprises at least a first

Fastening unit (150) and/or at least one second fastening unit (150), and the at least one first fastening unit (150) is adjacent to the first side (S1) and the at least one second fastening unit (150) is adjacent to the second side (S2), wherein the at least one first and/or second fastening unit (150) is designed to arrange the contacting unit (100, 100', 100"), in particular the base body (1 10), by clamping the respective fastening unit (150) between the stator housing and the electronics housing.

15. Electric motor comprising a contacting unit (100, 100', 100") according to one of the preceding claims.

16. Vehicle (300) comprising a contacting unit (100, 100', 100") according to one of claims 1 to 14 and/or an electric motor according to claim 15.