BATTERY UNIT, SYSTEM AND METHOD FOR ASSEMBLY OF THE SYSTEM

Abstract

A battery unit is provided. A high current power supply system comprising the battery unit is also disclosed. The battery unit comprises an electrode. The electrode further comprises a clamp.

Description

FIELD OF THE DISCLOSURE

The invention pertains to a battery unit having an electrode. The invention also pertains to a system with a battery unit and a busbar. The invention also pertains to a system with a battery unit and a further battery unit. The invention also pertains to a method for assembly of a system of a first battery unit, a second battery unit and a busbar.

BACKGROUND

Electrical batteries have become more and more important for various technical fields. In particular, this applies to relatively powerful battery sets for the energy supply to electrical motors. An important and technically demanding field is the energy supply to electrical vehicle motors, in particular street vehicles.

Here and in many other applications, battery sets comprising a plurality of battery units are commonly used. The battery units can be connected in parallel and/or in series in order to add up currents and/or voltages to meet the demands of the consumer, in particular the motor.

From WO 2019/242917 A1 a connector (referred to as “Modulverbinder” in WO 2019/242917 A1) suitable to hold an end of a flexible conductor (referred to as “flexible Stromschiene”) in contact with an electrode (referred to as “Pol”) of a battery is known. The known connector comprises a clamp (referred to as “Halteklammer”), the clamp having a transition section connecting a first leg arranged at one end of the transition section to a second leg arranged at the opposite end of the transition section. The first leg has a tip and the second leg has a tip. The transition section has a width in a width direction that extends at an angle to a line that connects the one end with the opposite end of the transition section. WO 2019/242917 A1 teaches to use the flexible conductor to compensate tolerance between electrodes of batteries that are to be connected. The production of flexible conductors is, however, expensive.

From JP 2012-38558 A a connector suitable to hold an end of a conductor in the form of an angled sheet metal (reference sign 60 in FIG. 5 of JP 2012-38558 A) in contact with a pin-shaped electrode (reference sign 12A or 12B in FIG. 5 of JP 2012-38558 A) of a battery is known. The known connector comprises a clamp (reference sign 80, 80A, 80B in FIG. 5 of JP 2012-38558 A), the clamp having a transition section (reference sign 81 in FIG. 5 of JP 2012-38558 A) connecting a first leg (reference sign 82 in FIG. 5 of JP 2012-38558 A) arranged at one end of the transition section to a second leg (reference sign 82 in FIG. 5 of JP 2012-38558 A) arranged at the opposite end of the transition section. The first leg has a tip and the second leg has a tip. The transition section has a width in a width direction that extends at an angle to a line that connects the one end with the opposite end of the transition section. FIG. 7 and FIG. 11 of JP 2012-38558 A show, how the connector is applied to the electrode of the battery. In a first step the angled sheet metal conductor is placed onto the pin-shaped electrode (see FIG. 11). In a second step the clamp is pushed over the pin-shaped electrode and the upwardly bent part of the angled sheet metal conductor.

Given this background, the problem to be solved by the invention is to suggest a battery unit, a system and a method that needs less parts and can be assembled more easily.

BRIEF SUMMARY

This problem is solved by the battery unit, the systems, and the method disclosed herein. Further embodiments are included in the description following hereafter.

The invention is based on the basic concept to have the electrode of the battery unit comprise a clamp. While prior art battery units invest minimal efforts into the design of the electrode and provide at least one separate clamp to secure the connection between electrode and busbar, the present invention provide the clamp already as part of the electrode

The electrode according to the invention comprises a clamp, whereby the clamp has a first leg and a second leg. The clamp also has a transition section. The first leg is arranged at one end of the transition section. The second leg is arranged at the opposite end of the transition section. The transition section hence connects the first leg to the second leg. In its most minimal form, the transition section is the line where the first leg and the second leg meet, such as in a V-shape. In this minimal embodiment of the transition section, the one end of the transition section and the opposite end of the transition section become one. In one embodiment, however, one end of the transition section is arranged at a distance from the opposite end of the transition section giving the transition section a length. It could, for example, be the basis of a U-shape.

The first leg is arranged at one end of the transition section. In one embodiment, the transition section is provided by a part of the clamp, which part has a length and a width and will be referred to as bridge.

In one embodiment, the first leg is arranged at one end of the transition section and the second leg is arranged at the opposite end of the transition section by way of a part of the first leg being attached to a part of the second leg. In such an embodiment, the transition section of the clamp would be that section of the clamp that contains the part of the first leg that is connected to the part of the second leg, the part of the second leg that is connected to the part of the first leg and—if necessary and provided—the elements for connecting the first leg to the second leg.

In one embodiment, the first leg and the second leg are parts of an integral or one-piece element. In one embodiment, the first leg and the second leg are provided by bending a blank. In such an embodiment, the transition section could be the bend that is introduced into the blank in order to create the first leg and the second leg. In an alternative, a part of the first leg could be connected to a part of the second leg by way of welding or gluing. In an alternative embodiment, a part of the first leg can be attached to a part of the second leg by way of using connecting elements, for example screws or rivets.

In one embodiment, in which the transition section is provided by a bridge, the first leg and the bridge are part of a one-piece element. In one embodiment, the first leg and the bridge are provided by bending a blank.

In one embodiment, in which the transition section is provided by a bridge, the first leg, the second leg and the bridge are part of a one-piece element. In one embodiment, the first leg, the second leg and the bridge are provided by bending a blank.

In one embodiment, in which the transition section is provided by a bridge, the second leg and the bridge are part of a one-piece element. In one embodiment, the second leg and the bridge are provided by bending a blank.

In one embodiment a third leg is provided, the third leg

• • being also arranged at the opposite side of the transition section and hence at the same side of the transition section as the second leg
  • the third leg being elastically deformable,
  • the clamp having a third state, in which the reference part of the first leg is distanced from a reference part of the third leg by a third amount,
  • the clamp having a fourth state, in which the reference part of the first leg is distanced from the reference part of the third leg by a fourth amount that is different from the third amount,
  • the transition section and/or the first leg and/or the third leg being further elastically deformed in the fourth state than in the third state. In some embodiments, the third state is the same as the first state such that the first amount and third amount are the same. In certain embodiments, the fourth state is the same as the second state such the second amount and the fourth amount are the same.

In one embodiment a third leg is provided, whereby

• • a further transition section is provided that connects the first leg to the third leg, the first leg being arranged at one end of the further transition section and the third leg being arranged at the opposite end of the further transition section,
  • the further transition section and/or the third leg being elastically deformable,
  • the clamp having a third state, in which a reference part of the first leg is distanced from a reference part of the third leg by a third amount,
  • the clamp having a fourth state, in which the reference part of the first leg is distanced from the reference part of the third leg by a fourth amount that is different from the third amount,
  • the further transition section and/or the first leg and/or the third leg being further elastically deformed in the fourth state than in the third state. In some embodiments, the third state is the same as the first state such that the first amount and third amount are the same. In certain embodiments, the fourth state is the same as the second state such the second amount and the fourth amount are the same.

In one embodiment, the transition section and the further transition section are arranged parallel to each other.

In one embodiment, the clamp is an one-piece element that is obtained by cutting and bending a blank, or, in specific embodiments, a metal blank. In an alternative, the clamp is provided by connecting individual pieces together. In one embodiment, the transition section and the second leg are provided as a one-piece element, for example an element obtained by cutting and bending a blank, whereby this one-piece element is attached to a further element, for example a further part of the electrode, for example a part of the electrode that extends deeper into a casing of the battery unit, whereby the further element, for example the further part of the electrode provides the first leg.

In one embodiment, the transition section and/or the first leg is elastically deformable. In one embodiment, the transition section and the first leg are elastically deformable. In one embodiment, only the transition section, but not the first leg is elastically deformable. In one embodiment, only the first leg and not the transition section is elastically deformable. In one embodiment, the second leg is elastically deformable. In one embodiment, the transition section, the first leg and the second leg are elastically deformable. In one embodiment, the transition section and the second leg, but not the first leg are elastically deformable. In one embodiment, the first leg and the second leg but not the transition section are elastically deformable. In one embodiment, the transition section is elastically deformable, but none of the first leg and the second leg is elastically deformable. In one embodiment, a third leg is provided and is leg is elastically deformable. In one embodiment, the transition section, the first leg, the second leg and the third leg are elastically deformable. In one embodiment, the transition section and the second leg and the third leg, but not the first leg are elastically deformable. In one embodiment, the first leg and the second leg and the third leg but not the transition section are elastically deformable. In one embodiment, the transition section and the first leg, but none of the second leg and the third leg are elastically deformable. In one embodiment, the transition section, but none of the first leg and second leg and the third leg are elastically deformable. The term “elastically deformable” is understood to mean that the application of a force not higher than 1000 Newton is necessary to move the clamp from the first state into the second state, wherein the upper limit may be 800 N, 600 N, 400 N, 300 N or 250 N.

The clamp of the connector according to the invention has a first state, in which a reference part of the first leg is distanced from a reference part of the second leg by a first amount. The clamp of the connector according to the invention also has a second state, in which the reference part of the first leg is distanced from the reference part of the second leg by a second amount that is different from the first amount. In one embodiment, the second amount is larger than the first amount.

In one embodiment the first leg has at least one part that is arranged closer to the second leg in the first state and the second state compared to other parts of the first leg. In one embodiment, the reference part is that one part. In one embodiment, the first leg has a point or a line on its surface that is arranged closest to the second leg in the first state and the second state compared to other parts of the first leg. In one embodiment the reference part is the part of the first leg that provides this point or this line. The reference part can be a tip of the first leg. The reference part can be a protrusion arranged on the first leg that protrudes over other parts of the first leg, or alternatively protrudes over other parts of the first leg that are arranged in a plane. The protrusion that forms the reference part can be a protrusion that is rounded and convex in two non-parallel sectional planes.

In one embodiment the second leg has at least one part that is arranged closer to the first leg in the first state and the second state compared to other parts of the second leg. In one embodiment, the reference part is that one part. In one embodiment, the second leg has a point or a line on its surface that is arranged closest to the first leg in the first state and the second state compared to other parts of the second leg. In one embodiment the reference part is the part of the second leg that provides this point or this line. The reference part can be a tip of the second leg. The reference part can be a protrusion arranged on the second leg that protrudes over other parts of the second leg, or alternatively protrudes over other parts of the second leg that are arranged in a plane. The protrusion that forms the reference part can be a protrusion that is rounded and convex in two non-parallel sectional planes.

In one embodiment the third leg has at least one part that is arranged closer to the first leg in the first state and the second state compared to other parts of the third leg. In one embodiment, the reference part is that one part. In one embodiment, the third leg has a point or a line on its surface that is arranged closest to the first leg in the first state and the second state compared to other parts of the third leg. In one embodiment the reference part is the part of the third leg that provides this point or this line. The reference part can be a tip of the third leg. The reference part can be a protrusion arranged on the third leg that protrudes over other parts of the second leg, or alternatively protrudes over other parts of the second leg that are arranged in a plane. The protrusion that forms the reference part can be a protrusion that is rounded and convex in two non-parallel sectional planes.

In one embodiment,

• • the first leg has a reference part, which may be only a reference part that is provided by a protrusion that is rounded and convex in two non-parallel sectional planes and
  • the second leg has a reference part, which may be only a reference part that is provided by a protrusion that is rounded and convex in two non-parallel sectional planes and
  • the third leg has a reference part, which may be only a reference part that is provided by a protrusion that is rounded and convex in two non-parallel sectional planes.

According to the invention, the transition section and/or the first leg is further elastically deformed (more elastically deformed, stronger elastically deformed) in the second state than in the first state. Embodiments are feasible, wherein the transition section and the first leg are not elastically deformed when the clamp is in the first state. The clamp in the first state in this embodiment could hence be considered to be unloaded. Alternative embodiments are also feasible, however, wherein the transition section and/or the first leg are elastically deformed already in the first state, but in the transition section and/or the first leg are further elastically deformed in the second state. In such an embodiment, the clamp could be considered to already be preloaded in the first state.

In one embodiment the transition section has a width in a width direction. The width direction extends at an angle, alternatively at an angle of 90°, to a line that connects the one end with the opposite end of the transition section. In one embodiment, if several lines can be drawn that connect the one end with the opposite end, especially in those embodiments, where the first leg and/or the second leg also extend to the width direction and hence one end or the opposite end of the transition section also have a dimension into the width direction, the shortest line that connects the one end with the opposite end of the transition section is used to define the width direction; the width direction being that direction that extends at an angle, which may be at an angle of 90° to that shortest line that connects a part of the one end of the transition section with a part of the opposite end of the transition section.

In one embodiment, there is at least one plane perpendicular to the width direction that contains a part of the reference part of the first leg and a part of the reference part of the second leg. In addition or as an alternative, there is at least one plane that is perpendicular to the width direction that contains a part of the reference part of the first leg but does not contain a part of the reference part of the second leg. In addition or as an alternative, there is at least one plane that is perpendicular to the width direction that contains a part of the reference part of the second leg but does not contain a part of the reference part of the first leg.

In one embodiment the first leg of the clamp has a tip and the second leg of the clamp has a tip and—if provided—the third leg of the clamp has a tip. The reference part of the first leg may be provided by the tip. The reference part of the second leg may be provided by the tip. The term “tip” refers to a free end of the first leg and the second leg, respectively. The term “tip” does not define the exact geometric shape of that free end of the first leg and the second leg, respectively. The tip of the first leg and the second leg, respectively, can In one embodiment have the geometric shape of a point. In such an embodiment, wherein the material of the first leg and the material of the second leg, respectively, converge towards the point-shaped tip. In a certain embodiment, the tip has a longitudinal extent. In one embodiment, the tip of the first leg and the tip of the second leg have the same geometric shape. In an alternative embodiment, the tip of the first leg has a different geometric shape to the geometric shape of the tip of the second leg.

In one embodiment, the clamp provides the end section of the electrode, the electrode having further parts, which terminate in the clamp. In one embodiment, the electrode terminates in a tip of the second leg—and if provided—in the tip of a third leg, while the first leg is connected to, for example by welding, or made as one piece with the further parts of the electrode. In one embodiment, the further parts of the electrode extend into a casing of the battery unit. In one embodiment, the clamp is arranged outside a casing of the battery unit, while the further parts of the electrode extend into a casing of the battery unit.

In one embodiment a spring clamp is provided that at least partially grips around the clamp.

In one embodiment a connector is provided that is suitable to hold a busbar in contact with the clamp.

In one embodiment, the connector has a casing with an opening for inserting a part of the busbar into the casing, whereby a clearance being arranged in the casing between the opening and a space between the first leg and the second leg.

The invention also pertains to a system of a battery unit according to the invention and a busbar held in contact with the clamp.

In one embodiment a further battery unit according to the invention is provided, whereby the busbar is also being held in contact with the clamp of the further battery unit.

The invention also pertains to a system of a battery unit according to the invention and a further battery unit that are arranged inside a casing of the system, the battery unit and the further battery unit being electrically connected to each other and to the electrode of the battery unit.

In one embodiment, a part of the busbar is arranged between the first leg, in some embodiments between the reference part of the first leg and the second leg, in certain embodiments between the reference part of the second leg of the clamp. In one embodiment, the first leg, in some embodiments the reference part of the first leg is in contact with a surface of the busbar. In one embodiment, the second leg, in some embodiments the reference part of the second leg also is in contact with a surface of a busbar. In one embodiment, the first leg, in certain embodiments the reference part of first leg is in contact with a first surface of the busbar and the second leg, in particular embodiments the reference part of the second leg is in contact with a second surface of the busbar, whereby the first surface and the second surface are arranged on opposite sides of the busbar and are pointing away from each other. In one embodiment, the first surface and the second surface are parallel to each other.

The system according to the invention can have a plurality of battery units, in specific embodiments a plurality of battery units according to the invention.

So-called busbars are used as electrical conductors for example for interconnecting battery units with each other or battery sets with a consumer. A busbar is often bar-shaped or strip-shaped but the term “busbar” shall be understood without an implicit geometric meaning herein, more as a general term for connectors in the field of electrical power distribution as described above.

Such busbars need to be interconnected in certain situations as well, for example in order to extend their longitudinal coverage by combining a plurality of interconnected busbars. This could serve for connecting a battery unit to a consumer, as an example. When connecting a busbar to a battery unit, the busbar has to be brought into an electrical contact with an electrode of the battery unit, instead. A combination, namely the interconnection of at least two busbars and of at least one of them with an electrode, is also comprised.

According to the invention, a clamp having at least two clamp legs is used as a part of the contact system. At least one of the clamp legs shall be elastically moveable by means of an elastic deformation of the leg itself and/or another clamp part to which it is connected such as a bridge spacing the leg from another leg or to a bridge or a transition to another leg of the clamp. The elastic movability results in a variability of an interspace between the clamp legs so that the clamp legs are actually elastically biased with regard to any movement changing the interspace. For example, such a movement could vary the angle of a more or less V-shaped clamp or vary the interspace between the legs of a more or less U-shaped clamp by a variation of at least one of the angles and/or the shape of a transition section, namely of the base or bridge of the U-shape between the legs.

Such a clamp can be made up of several parts but may be implemented integrally in terms of the clamp legs and a clamp part therebetween, if any. Moreover, it is also possible to implement a clamp having a plurality of parts whereof for example at least one part is adapted to (and optimised in view of) an electrical contact and current transport to and through the clamp or parts thereof, namely an electrical function of the clamp. At least one further part could be adapted to (and optimised in view of) a mechanical function of the clamp, namely providing the elastic restoring force or a substantial part thereof. This is generally known in the art for example by using a spring steel structure as the mechanical part or “spring clamp” and for example a copper structure as the electrical part or “conductive clamp”.

Of course, the above discussed mechanical function and electrical function can also be combined within one and the same integral clamp. Still further, within the present application, a “clamp” does not necessarily have the electrical function in terms of participating in the electrical conduction itself in a substantial or any extend. It is also conceivable to have a clamp in the present sense serving just for the mechanical function, for example to hold a busbar and an electrode together so as to establish and/or maintain an electrical contact between the busbar and the electrode. Therein, the current or at least a major part thereof could directly go from the busbar to the electrode or vice versa and only a minor part or no current at all flow through the clamp or parts thereof. In particular, such a clamp need not be electrically conductive at all.

On the other hand, a “spring clamp” having a mechanical function as described does not necessarily provide for the complete contact force required for the electrical contact (the clamp participating therein or not) but can be combined with further means for providing an additional contribution to the contact force.

Herein, the term “clamp” shall relate to any clamp having the described properties of clamp legs with a variable interspace and a movability of at least one clamp leg (caused by elasticity) for the variation of this interspace, whether the clamp has a substantial electrical function or not.

Still further, the elastic restoring force may, but does not necessarily, tend to decrease the interspace between the clamp legs, that is for example to decrease the angle between the legs of a V-shaped clamp. Thereby the parts to be connected and brought into electrical contact are held together, for example portions of at least two busbars or at least one busbar and an electrode.

For establishing the electrical contact by means of the contact system, the busbar and the further busbar or the busbar and the electrode shall be clamped by the clamp, in other words they shall be held in close mechanical contact with each other by means of the elastic restoring force of the clamp. The surface portions of the respective parts in contact with each other are referred to as contact surfaces, herein. Thus, the at least one clamp leg has a clamp leg contact surface, the busbar has a busbar contact surface and so on. At least a part of these contacts between the contact surfaces are relevant for the electrical current flow but, as explained above, not necessarily all of them.

In order to maintain a reliable and low resistance contact, the mechanical and thus (at least in part) also electrically relevant fixing provided by the clamp shall withstand typical disturbances in the practical application and lifetime of the contact system. The inventors have found that geometrical tolerances, variations and movements are a very important factor in this respect, in particular, but not only, in the field of electrical power supply to motors and in vehicles.

Such disturbances can be caused by misalignments, errors or tolerances in mounting for example battery sets or busbar systems or other vehicle-related or consumer-related structures. They can occur during use by wear, vibrations and shocks, temperature variations and so on. In particular, the electrical parts themselves, such as battery parts, including electrodes, busbars, clamps, can be heated by electrical resistance losses (“Joule heat”) during use and experience quite substantial temperature variations.

In this respect, the invention aims at a contact system tolerant in view of mechanical and geometric tolerances and variations. Hereto, the inventors have found that at least one convex protrusion on at least one of the above-mentioned contact surfaces (of a busbar, an electrode, a clamp leg) is very helpful. Therein, the convexity shall apply to two sectional planes which are vertical to each other. In other words, a convex rib extending along a direction and limited only in a direction perpendicular thereto, is convex only in one sectional plane (perpendicular to the longitudinal direction thereof), but for example a spherical protrusion is two-dimensionally convex.

If, for example, the contact surface having a protrusion and the further contact surface in contact therewith are tilted with regard to each other by a limited amount, the convex protrusion can so to say “roll” on the respective other contact surface. In other words, the mechanical contact between both contact surfaces has an “articulation character” due to the convexity of the protrusion.

In certain embodiments, the at least one convex protrusion is rounded, for example spherical, elliptical, egg-shaped, in the sectional planes already referred to. The rounded shape further improves the above-mentioned rolling or articulation properties.

If, as another example, the two contact surfaces are shifted relative to one another (in a direction substantially in a plane perpendicular to the two sectional planes of the convexity), the protrusion can slide along the other contact surface in a smoother and more continuous and controlled manner compared for example to parallel plane surfaces, namely due to its rounded shape. In particular, the location of the actual current carrying contact, where the protrusion lays against the other contact surface, will normally not jump or substantially change the shape, as it could happen with parallel plane surfaces sliding or being tilted relative to each other.

Even not rounded convex shapes can have sufficient sliding properties in this respect depending on the material chosen for the protrusion and its counterpart.

Thus, depending on the individual situation, at least two shifting directions or directions of linear tolerance or linear vibration amplitudes can be covered to a certain extent that depends on the size and structure of the respective parts of the contact system. This does not necessarily apply also to directions in the plane perpendicular to the two sectional planes of the convexity, but due to the elasticity of the clamp and a resilient reaction thereof, also other directions can be part of a geometric tolerance of the contact system.

Likewise with regard to tilting axes: the convex protrusion as a “rolling structure” can tolerate rotations of limited amount around axes substantially in the underlying plane (being perpendicular to the two sectional planes of the convexity) and the elasticity of the clamp can help therein. Also tilting movement around a third axis can be possible due to the defined and limited location of the actual contact.

The protrusion need not be spherical but can be spherical. Nevertheless, it can be characterised at least in a rough manner by using a radius of curvature in a local sense. This relates for example to the case that the radius of curvature depends on whether the location considered is more central in the protrusion or more outward. For example, the protrusion can be less rounded in its center and somewhat more rounded outwards thereof. Included is also the case that the radius of curvature depends on the direction of the sectional plane chosen. In particular, the present explanations on the rounded shape of the protrusion mainly applies to those regions which are relevant for the contact in the normal operation of the contact system, i. e. those parts of the protrusion which are relevant for the above explained rolling or shifting movements.

The radius of curvature of the protrusion in the above sense may be at most 40 mm, wherein some embodiments the upper limits are as follows: 35 mm and 30 mm. Potential lower limits for the radius of curvature of the protrusion are 5 mm, 10 mm, and 15 mm.

On the other hand, the respective other contact surface, namely the contact surface contacting the protrusion, may be substantially flat in a portion relevant for the contact, namely it has a flat portion for contacting the protrusion. “Flat” is not to be understood in a mathematical sense but just shall mean that the portion is not too rounded or edge-shaped. In particular, an average radius of curvature in the above sense can be used again. Further, as above, the explanations and geometrical features relate to those portions that are relevant for the contact, in particular the rolling or shifting movements explained, compare also below.

Thus, the radius of curvature of the flat portion in the above sense may be at least 100 mm, wherein in some embodiments the lower limits are as follows: 200 mm, 300 mm, 400 mm and even 500 mm.

Generally, the convex protrusion can “roll” over another surface portion that is for example also rounded and convex. However, the above-mentioned tolerance with regard to linear misalignments, movements or vibrations can be improved by the combination of a rounded convex protrusion on the one side and a substantially flat portion of the contact surface on the other side. This is the result of the flat portion not changing very much with a shifting along its surface and that it provides a basis for a sliding movement of the protrusion without implying large geometrical variations in other directions thereby.

In some embodiments, the size of the protrusion on the one hand and the flat portion on the other hand (if existent at all) can be characterised by an average diameter in a projection into the plane perpendicular to the two sectional planes of the convexity. This average diameter does not imply a circular shape but would also characterise for example a square in terms of the average of diagonal and of the longer and the shorter side. The average diameter can be at least 10 mm or even at least 15 mm or 20 mm. In some embodiments, it can be at most 50 mm or even at most 40 mm or 35 mm.

In a special embodiment of the invention, in some embodiments, the respective other contact surface contacting the protrusion is not flat as described above but concave. Beside the obvious fact that a “flat” portion under the definition above, i. e. with a sufficient radius of curvature, can be concave and nevertheless provide for the properties explained, also a concave shape having smaller radii of curvature is contemplated. In particular, such a concave shape can have an even smaller radius of curvature than the protrusion in one sectional plane and a larger one than the protrusion in a further sectional plane vertical to the first one. In other words, it is somewhat lengthy and the protrusion will contact two locations usually at the border of the concave structure. Therefore, the contact is split in two contact locations allowing for a lower contact resistivity. The contact force (or “load”) is distributed between the two contact locations. Due to the lengthy oblong shape of the concave structure or “groove”, the protrusion can be shifted along the longitudinal extension of the groove.

According to a further aspect of the invention, the parts to be clamped and connected by the clamp can have a simple structure, in particular a substantially square shape (meaning three-dimensionally rectangular and not withstanding rounded edges as shown in the embodiments). Of course, this applies in particular to the portion clamped by the clamp, for example for the busbar. Such a busbar is often specifically shaped in order to penetrate a battery casing and to reach a structure to be contacted within the battery unit. Nevertheless, an end portion relevant for the contact system can be square.

Naturally, a square shape in this sense does not withstand a protrusion in the above meaning and, of course, offers various options for flat portions to be contacted by a protrusion. Thus, a combination of such a square-shaped busbar with another part, in particular another busbar, wherein a protrusion on one of the combined parts is provided. However, the clap legs or at least one of them can also be used to provide the protrusion as one of the embodiments shows. Nevertheless, in particular embodiments the current or at least a major portion thereof directly goes from a busbar or an electrode into another busbar, and then, a protrusion should be provided at the respective contact.

As regards the elastic movability, it has been defined that at least one clamp leg shall be elastically moveable to implement the clamp function. If, for example, one leg of a U-shaped clamp would be moveable by means of an elastic deformability of the leg, a connection to the bridge of the U-shape or of the bridge itself, still the other leg could be rigid and the interspace between both legs be variable nevertheless. For example, this could be an option if the one rigid leg was fixed to a part of the battery casing or even was an integral part thereof.

However, both or all legs may be elastically moveable (or even deformable). Such clamps are more flexible, in particular if they are independent of the battery casing.

In certain embodiments, the flat portion discussed above is, in the mounted state, substantially parallel to a direction of the longest extension of the or at least one busbar. This is advantageous with regard to a thermal expansion or contraction of the busbar resulting in variations along this longitudinal direction and thus in the already described shifting movements along the flat portion. If these are quantitatively relevant or even dominant variations to be considered, they can be tolerated in a quite substantial amount, this being easier than for example providing for such movements by elastic movements of clamp legs.

Generally, the clamp has at least two legs. In particular embodiments, it can have at least and, in specific embodiments, exactly three legs, namely two on one side and at least one (and in some embodiments, exactly one) on the other side of the interspace. Such a so to say tripod-like structure can very stably hold an electrode and/or a busbar or several busbars. Due to the splitting into two legs on at least one side, these legs can react independently of each other as regards their elastical motion.

The invention also provides a method for assembly of a system. The method at least comprises the steps of

• • providing a first battery unit according to the invention,
  • providing a second battery unit according to the invention,
  • providing a busbar,
  • bringing a part of the busbar into contact with the clamp of the first battery and bringing a further part of the busbar into contact with the clamp of the second battery unit.

In one embodiment the connector has a casing with an opening that at least partially can be closed with a lid, whereby the method includes the step of moving the lid from a position where it does not close the opening or closes the opening to a lesser extend into a position where it at least partially closes the opening.

In one embodiment, where the method according to the invention is used to assemble a system, whereby the system contains a further battery unit, in certain embodiments a further battery according to the invention, whereby one end of the busbar is in contact with the clamp of the one battery unit and whereby a second end of the busbar is in contact with the clamp of the further battery unit, the one end the busbar is brought into contact with the clamp of the one battery unit at the same time as the second end of the busbar is brought into contact with the clamp of the second battery unit.

In one embodiment, where the method according to the invention is used to assemble a system, whereby the system contains a further battery unit, in some embodiments a further battery according to the invention, whereby one end of the busbar is in contact with the clamp of the one battery unit and whereby a second end of the busbar is in contact with the clamp of the further battery unit, the one end the busbar is brought into contact with the clamp of the one battery unit first and afterwards the second end of the busbar is brought into contact with the clamp of the second battery unit.

In one embodiment, the busbar is a longitudinal object that extends along a longitudinal axis. In one embodiment, the cross-sectional area of the busbar has the same size in the majority of sections of the busbar perpendicular to the longitudinal axis, alternatively in the overwhelming majority (more than 75%) of the cross-sections of the busbar perpendicular to the longitudinal axis and further alternatively in all cross-sections of the busbar perpendicular to the longitudinal axis.

In one embodiment, the shape of the cross-sectional area of the busbar is the same in the majority of sections of the busbar perpendicular to the longitudinal axis, alternatively in the overwhelming majority (more than 75%) of the cross-sections of the busbar perpendicular to the longitudinal axis and further alternatively in all cross-sections of the busbar perpendicular to the longitudinal axis.

In one embodiment, the cross-sectional area of the busbar is rectangular or round or elliptical in the majority of sections of the busbar perpendicular to the longitudinal axis, alternatively in the overwhelming majority (more than 75%) of the cross-sections of the busbar perpendicular to the longitudinal axis and further alternatively in all cross-sections of the busbar perpendicular to the longitudinal axis.

In one embodiment, the cross-sectional area of the busbar is rectangular and has a width and a height in the majority of sections of the busbar perpendicular to the longitudinal axis, alternatively in the overwhelming majority (more than 75%) of the cross-sections of the busbar perpendicular to the longitudinal axis and further alternatively in all cross-sections of the busbar perpendicular to the longitudinal axis, whereby the width alternatively is 10 mm to 50 mm, alternatively 20 mm to 30 mm and/or the height alternatively is 1.5 mm to 5 mm, alternatively 2 mm to 3.5 mm. In some embodiments, the cross section can be between 50 mm² and 120 mm².

In one embodiment, the length of the busbar is more than 20 mm, alternatively more than 30 mm, 40 mm or even 50 mm. In one embodiment, the length of the busbar is smaller than 500 mm, alternatively smaller than 400 mm, 300 mm even smaller than 250 mm.

In one embodiment, this busbar has a thermally and electrically well conducting material, in particular a material having a conductivity of at least 107 S/m (at 20° C.). One option is copper, in particular high purity electrical grade copper (ETP copper) or aluminum, more specifically electrical grade aluminum (such as 1000 or 6000 series).

In a possible embodiment, the busbar has a core that is made from a core material and has an insulation whereby the insulation encapsules at least a part of the core. The above also holds for the core material, namely that a thermally and electrically well conducting material may be used.

In one embodiment, the busbar that has a core and an insulation has one free end that is not encapsulated by the insulation and has a second end that is arranged opposite to the first end that also has no insulation. In one embodiment, the length of the free end that has no insulation is more than 5% of the total length of the busbar and is less than 30% of the total length of the busbar.

In one embodiment, the electrode has a further portion that extends away from the clamp.

In one embodiment, the further portion of the electrode is a longitudinal object that extends along a longitudinal axis. In one embodiment, the cross-sectional area of the further portion of the electrode has the same size in the majority of sections of the further portion perpendicular to the longitudinal axis, alternatively in the overwhelming majority (more than 75%) of the cross-sections of the further portion of the electrode perpendicular to the longitudinal axis and further alternatively in all cross-sections of the further portion of the electrode perpendicular to the longitudinal axis.

In one embodiment, the shape of the cross-sectional area of the further portion of the electrode is the same in the majority of sections of the further portion perpendicular to the longitudinal axis, alternatively in the overwhelming majority (more than 75%) of the cross-sections of the further portion of the electrode perpendicular to the longitudinal axis and further alternatively in all cross-sections of the further portion of the electrode perpendicular to the longitudinal axis.

In one embodiment, the cross-sectional area of the further portion of the electrode is rectangular or round or elliptical in the majority of sections of the further portion perpendicular to the longitudinal axis, alternatively in the overwhelming majority (more than 75%) of the cross-sections of the further portion of the electrode perpendicular to the longitudinal axis and further alternatively in all cross-sections of the further portion of the electrode perpendicular to the longitudinal axis.

In one embodiment, the cross-sectional area of the further portion of the electrode is rectangular and has a width and a height in the majority of sections of the further portion perpendicular to the longitudinal axis, alternatively in the overwhelming majority (more than 75%) of the cross-sections of the further portion of the electrode perpendicular to the longitudinal axis and further alternatively in all cross-sections of the further portion of the electrode perpendicular to the longitudinal axis. As regards the width and the height and the resulting cross section of the electrode end portion, these quantitative values given for the busbar apply as well.

In one embodiment, the length of the further portion of the electrode is more than 20 mm and it can for example be up to 50 mm long.

In one embodiment, the further portion of the electrode has a core that is made from a core material and has an insulation whereby the insulation encapsules at least a part of the core.

As regards a thermally and electrically well conducting material for the electrode and in particular its end portion and for the core material, if any, the explanations with regard to the busbar apply as well.

In one embodiment, the busbar is a solid object that is free from through-holes.

In one embodiment, the busbar and the electrode are not connected to each other by way of screws, bolts, nails, rivets or by way of welding or soldering. In one embodiment, the busbar is held in place by the clamp.

In one embodiment, the busbar is a longitudinal object that extends along a longitudinal axis and the further portion of the electrode is a longitudinal object that extends along a longitudinal axis. In one embodiment, the longitudinal axis of the busbar is parallel to the longitudinal axis of the further portion of electrode. In these embodiments, alternative embodiments are feasible, where the busbar and the further portion of the electrode extend away from the area where they are in contact in the same direction. In such an embodiment, the further portion of the electrode would extend in one direction and the busbar would extend back into the direction the further portion of the electrode extended from. In an alternative of these embodiments, the busbar extends away from the area where they are in contact into one direction and the further portion of the electrode extends into a different direction that is not parallel to the one direction. In such an embodiment, the busbar could be in line with the further portion of the electrode. In alternative embodiments, the longitudinal axis of the busbar is arranged at an angle between 20° and 160°, alternatively in an angle of 45° to 135°, alternatively in an angle from 75° to 105° and alternatively at an angle of 90° to the longitudinal axis of the further portion of the electrode.

The invention also relates to a battery set comprising a plurality of battery units, namely at least two, each of which having at least two electrodes. Here, a busbar is provided for electrically connecting at least two of these electrodes wherein each one of the two belongs to another battery unit. At least one of the above described contact systems serves for connecting the busbar with at least one of the electrodes. Naturally, there is one contact system for each electrode participating in the interconnection is typical and two such contact systems share their busbar.

Alternatively, their busbars are interconnected by a further contact system (to which both busbars belong as well).

In one embodiment the potential difference between one electrode of a battery unit and the further electrode of the battery is more than 200 V or even 250 V, 300 V or 350 V. In one embodiment the potential difference between one electrode of a battery unit and the further electrode of the battery is less than 1200 V, alternatively less than 1100 V, 1000 V or even less than 900 V.

In one embodiment the capacity of the battery set is more than 20 kWh.

In one embodiment the battery set is used as a battery of an electric car.

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing aspects and many of the attendant advantages will become more readily appreciated as the same becomes better understood by reference to the following detailed description, when taken in conjunction with the accompanying drawings, wherein like reference numerals refer to like parts throughout the various views, unless otherwise specified:

FIG. 1 a schematic perspective view onto an array of battery blocks;

FIG. 2 a schematic enlarged perspective view of a portion of the array of battery blocks of FIG. 1;

FIG. 3 a schematic exploded perspective view of the elements of a connector, an electrode and a busbar;

FIG. 4 a schematic exploded perspective view showing a clamp and a casing of a connector;

FIG. 5 a schematic perspective view showing the clamp and the casing of FIG. 4 in assembled form;

FIG. 6 a schematic sectional perspective view showing the clamp and the casing of FIG. 4 in assembled form;

FIG. 7 a schematic perspective view onto the clamp and the casing of FIG. 4 in assembled form with a spacer;

FIG. 8 a schematic exploded perspective view onto the clamp and the casing and the spacer of FIG. 7 in assembled form and a lid;

FIG. 9 a schematic perspective view onto the clamp and the casing and the spacer and the lid of FIG. 8 in assembled form;

FIG. 10 a schematic perspective view onto a part of a battery block with a connector attached to it from a first perspective;

FIG. 11 a schematic perspective view onto the part of a battery block with the connector attached to it of FIG. 10 from a second perspective;

FIG. 12 a schematic perspective view onto a connector and a part of a busbar;

FIG. 13 a schematic sectional view onto the connector and the part of the busbar of FIG. 12 and an electrode;

FIG. 14 a schematic top view onto two connectors and a busbar arranged between the two connectors;

FIG. 15 a,b,c a sequence of sectional views onto a connector and a part of a busbar showing assembly steps of the part of the busbar and the connector;

FIG. 16a a schematic perspective view of an end of a busbar in contact with an electrode;

FIG. 16b a perspective view of a modified version of the busbar 4 of FIG. 3;

FIG. 16c a modified version of the schematic sectional view of FIG. 13, but with the busbar 4 of FIG. 16b;

FIG. 17a a schematic perspective view of an electrode;

FIG. 17b a schematic side view onto an electrode;

FIG. 18 a schematic illustration in top view;

FIG. 19 a schematic perspective view of the electrode of FIG. 18 and

FIG. 20 a schematic side view onto the electrode of FIG. 17 together with a spring clamp.

DETAILED DESCRIPTION

FIG. 1 shows an array 1 of battery blocks 2. In the embodiment shown in FIG. 1, the array 1 has eight battery blocks 2. Four battery blocks 2 each are grouped into one line of battery blocks 2. The two lines of four battery blocks 2 each are arranged in parallel to each other.

Each battery block 2 can comprise individual battery cells, not visible in the Fig., and connected for example in series. The term battery unit as used herein can relate to such a battery block, but also to a battery cell therein whereas the term battery set can relate to the array 1 or to the battery block 2.

Each battery block has two electrodes (not shown in FIG. 1), an electrode for providing the negative potential and one electrode for providing the positive potential. For each electrode, each battery block 2 is provided with a connector 3. Hence each battery block 2 has two connectors 3 in total. Between a connector 3 of one battery block 2 and a neighbouring connector 3 of a neighbouring battery block 2, a busbar 4 is arranged. The busbar 4 arranged at the end of the lines of battery blocks 2 is U-shaped. The other busbars 4 are bar-shaped.

For ease of reference, the connectors 3 shown in FIG. 1 are drawn with their lids 13 open. The same goes for FIG. 2.

The connector 3 as best seen in FIG. 3 contains a casing 10, a clamp 11, a spacer 12 and a lid 13. FIG. 3 additionally shows an electrode 5 of a battery block and a busbar 4.

The clamp 11 has a transition section 20 that in the embodiment shown in FIG. 3 is made up of a bridge 21. The clamp 11 has a first leg 22 arranged at one end of the transition section 20. Clamp 11 also has a second leg 23 that is arranged at the opposite end of the transition section 20. The first leg has a reference part 24 that in the embodiment shown in FIG. 3 is a longitudinal tip. The second leg 23 in the embodiment shown in FIG. 3 also has a reference part 25 that in the embodiment shown also is a longitudinal tip. The second leg 23 in the embodiment shown in FIG. 3 has an opening 26. The opening 26 allows the electrode 5 to be arranged on one side of the second leg 23 and for a spherical protrusion 6 of the electrode 5 to protrude through the opening 26 into the space between the first leg 22 and the second leg 23 (see for example FIG. 13).

It can be seen that protrusion 6 projects on and from a substantially square electrode contact surface and is adapted to lay against and contact a busbar contact surface, namely an end portion of busbar 4. This busbar contact surface is, in contrast to the protrusion, flat.

Clamp 11 is made by way of cutting and bending from a metal blank and hence is a unitary piece. The transition section 20, the first leg 22 and the second leg 23 are elastically deformable.

The clamp 11 has a first state shown in FIG. 3, FIG. 4 and FIG. 6 for example. In this first state, the reference part 24 and the reference part 26 are distanced from each other by a first amount. The clamp has a second state (see FIG. 7 for example), in which the reference part 24 and the reference part 25 are distanced from each other by second amount that is different from the first amount, namely larger than the second amount.

As can be seen when comparing FIG. 6 and FIG. 7, the transition section, the first leg and the second leg are not elastically deformed in the first state. In the first state, the clamp 11 takes up its normal form. At least one of the group of elements containing the transition section 20, the first leg 22 and the second leg 23 are further elastically deformed (more elastically deformed) in the second state than in the first state. As can be seen when comparing FIG. 6 and FIG. 7, the distance between the reference part 24 and the reference part 25 has been increased from the first state shown in FIG. 6 to the second state shown in FIG. 7. This increase in distance is achieved by elastically deforming at least one of the elements of the group that contains the transition section 20, the first leg 22 and the second leg 23.

The spacer 12 is movable between a first position best shown in FIG. 7 and FIG. 15a and a second position (best shown in FIG. 15c). As can best be seen from FIG. 7, the spacer 12 when it is in the first position is in contact with a part of the first leg 22 when the clamp 11 is in the second state (see FIG. 7).

As can best be seen from FIG. 15a, FIG. 15b FIG. 15c, the spacer 12 is designed to be rotated from the first position into the second position.

FIG. 3 and FIG. 7 for example show that two rods 30 extend from the spacer 12 along a rotational axis 31. As can be seen from FIG. 7 and FIG. 8, the rods 30 are arranged in holes 32 of the casing 10 and allow the spacer 12 to rotate relative to the casing 10 about the rotational axis 31.

FIG. 8, FIG. 9 and FIG. 12 show that the connector 3 has a lid 13. The lid 13 can be arranged in an open position (FIG. 9) on the casing 10. FIG. 12 shows the closed position of the lid 13 on the casing 10. On the casing 10, a knob 14 can be provided that holds the lid 13 in the open position (FIG. 9) and that needs to be overcome by the lid 13 as it is moved from the open position (FIG. 9) to the closed position (FIG. 12). As shown in FIG. 12, the knob 14 can also be used to hold the lid 13 in the closed position. The knob 14 is so to say a part of an elastic latch mechanism, the lid 13 providing for the required elasticity.

FIGS. 10 and 11 show that the connector 3 can be arranged at an end portion of the battery block 2. On one end, the connector 3 can have a projection 15 that in a form-fit manner engages with a recess on the battery block 2 (see FIG. 11). The casing 10 of the connector 3 can have a through-hole 16 that can be used to bolt the casing 10 to the battery block 2.

FIG. 12 shows a perspective view onto a connector 3 and a part of a busbar 4. To simplify the view of FIG. 12, the electrode 5 has not been drawn. FIG. 13 shows a sectional view onto the connector 3 and the part of the busbar 4 of FIG. 12 together with the electrode 5.

FIG. 13 shows that the flat end of the busbar 4 is in contact with the spherical protrusion 6 of the electrode 5. The first leg 22 rests against the busbar 4 from the opposite side compared to the protrusion 6. The first leg 22 hence holds the busbar 4 in contact with the protrusion 6 of the electrode.

FIG. 13 also shows that the protrusion 6 of the electrode 5 protrudes through the opening 26 in the second leg 23. The main body of the electrode 5 is arranged on the opposite side of the leg 23 compared to the side that the end of the busbar 4 is arranged on.

Given the shape of the protrusion 6 of the electrode 5, the end of the busbar can swivel about the axis A, the axis B and the axis C (which points out of the plane of the paper) to a certain degree without losing contact to the protrusion 6 or changing the very contact location at the tip of protrusion 6 in an uncontrolled manner (see also FIG. 16). Further, shifts along the directions of the axis A and C are possible by a sliding of protrusion 6 on the flat busbar contact surface.

The shape of the protrusion 6 and the arrangement of the busbar 4 in contact with the protrusion 6 hence allows for a large degree of tolerance compensation.

FIG. 14 shows a top view onto two connectors 3 with a busbar 4 arranged between the two connectors 3. FIG. 14 shows, how the busbar 4 has swivelled about the axis A in FIG. 13 in order to compensate a misalignment of the connectors 3.

The sequence of FIGS. 15a, 15b, 15c shows assembly steps of a system with a connector and a busbar. The electrode that is for example visible in FIG. 13 has been purposefully left out of the FIGS. 15a, 15b, 15c for a better overview. In FIG. 15a, the end of the busbar 4 is arranged outside the connector 3. FIG. 15a shows that there is a clearance between the opening 17 of the casing 10 and a busbar abutment surface 33 on the spacer 12. FIG. 15b shows the situation where the end of the busbar 4 has been inserted through the opening 17 into the casing 10 to the extent that it comes into contact with the busbar abutment surface 33. FIG. 15c shows the situation where the end of the busbar 4 has been fully inserted into the casing 10 by being moved from the situation shown in FIG. 15b to the situation shown in FIG. 15c leading to the spacer 12 being rotated from the first position (FIG. 15a) to the second position (FIG. 15c).

In a next step in the situation shown in FIG. 15c, lid 13 can be closed. The lid 13 can provide a stopper against the busbar 4 being pulled out of the connector 3.

FIG. 8 by way of a dotted line shows the extent of the opening 17 into which the end of the busbar 4 can be inserted into the casing 10.

As can be seen from FIG. 13, part of the busbar 4 is arranged between the reference part 24 and the reference part 25.

FIG. 16a shows a schematic perspective view of an end of a busbar 4 in contact with an electrode 5. The purpose of FIG. 16a is to highlight that the protrusion 6 as provided on the electrode 5 is a suitable means to allow the busbar 4 and the electrode 5 to perform relative movements, especially rotations about the three perpendicular axes A, B, C without the surface contact between the end of the busbar 4 and the electrode 5 being influenced. The embodiment shown in FIG. 16a shows the busbar 4 and the electrode 5 to be arranged in line, which means that the longitudinal axis of the busbar 4 is parallel to the longitudinal axis of the electrode 5 and/or parallel to the plane from which the protrusion 6 projects. It is apparent to the person skilled in the art, however, that the ability to keep the good surface contact between the end of the busbar 4 and the electrode 5 by means of the protrusion 6 even in situations, where the end of the busbar 4 and the electrode 5 tilt relative to each other about one of the perpendicular axes A, B, C will also be kept for those embodiments, where the busbar 4 is arranged perpendicular to the electrode 5 for example in the design shown in FIG. 13 or those embodiments, where a busbar and a further busbar are pointing in the same direction. FIG. 16a shows that the protrusion 6 is rounded and convex in two non-parallel sectional planes. The protrusion 6 is rounded and convex in the plane that contains the axis A and B and the protrusion 6 is rounded and convex in the plane that contains the axis B and C.

The protrusion 6 could of course also be an element of the busbar 4 instead of the electrode 5. This would not change the contents and discussion of FIG. 16a. This also applies with regard to FIGS. 3 to 15. Moreover, the protrusion could in some embodiments also be integrally formed in at least one of the clamp legs, for example in both of them, these protrusions contacting the busbar contact surface and the electrode surface, respectively.

Further, the design of the busbar and/or the electrode are generally kept as simple as possible. Such a simple busbar design and electrode design (at least of the electrode portion for making the contact and outside of the battery casing) can be square as shown, wherein shapes with somewhat rounded edges and protrusions as shown are included.

It goes without saying, that further elements of the connector 3 additional to the clamp, the busbar and the electrode will be adapted to the tolerances (with regard to rotations and shifts) contemplated by means of sufficient clearances. Since the casing predominantly has functions of protecting, insulating and holding the electrically relevant elements, this does not imply substantial differences and is clear to the person skilled in the art.

The busbar 4 as discussed so far and as shown in FIG. 3 has a flat portion to be contacted by the protrusion 6. FIG. 16b illustrates a modified version of the busbar 4, namely having two oval concave grooves 50 wherein the transition from the flat surface portions there around to the grooves 50 is somewhat rounded. As shown in FIG. 16c which can be compared to FIG. 13 and is a modified version thereof, the protrusion 6 is adapted for engaging into the respective groove 50 but the radius of curvature of the concavity of the groove 50 is substantially smaller than the radius of curvature of the protrusion 6. Therefore, the protrusion 6 contacts the rounded borders of the groove 50.

This applies to the vertical direction of the Figures. As regards the horizontal direction, the grooves 50 are longer than in the vertical direction by so to say including straight sections (in their profile as seen horizontally). Therefore, the protrusion 6 can shift within the groove 50 in case of horizontal relative movements, for example due to a thermal expansion of the busbar 4.

Further, the rolling movement in cases illustrated in FIG. 14 is still possible. Articulations around other axis would lead to some shifting movements as well (as in the case of the longitudinal shifting movement).

The grooves 50 have the advantage of splitting the contact load provided into two points which have a lower overall resistivity than just one contact point. Further, the oblong shape of the groove is particularly adapted for the already described relative movement in the longitudinal direction of the busbar 4 and some sense secures the engagement of the protrusion 6 into the groove 50 therein.

Beside that, the above explanations also apply to these modifications.

While in the embodiment shown in FIGS. 3 to 15, the electrode 5 is designed as a separate element from a clamp of a connector, the embodiment shown in the FIGS. 17a to 20 shows that the electrode 5 can have a part that provides the clamp 11. The clamp 11 that is part of the electrode 5, here, has a first leg 22, a second leg 23 and a third leg 27. The clamp 11 has in the embodiment of FIG. 17a two transition sections 20, which in the embodiments of FIG. 17a are made up as two separate bridges 21. In the embodiment shown in FIG. 19, the clamp 11 has one transition section 20 that is made up as one bridge 21. A first leg 22 is arranged at one end of the transition section 20. The second leg 23 is arranged at the opposite end of the transition section 20. The third leg 27 is arranged also at the opposite side of the transition section 21 in comparison to the arrangement of the first leg 22 that is arranged at one end of the transition section 20. Hence, the second leg 23 and the third leg 27 are arranged on one side when compared with the arrangement of the first leg 22 relative to the transition section 20.

Each of the first leg 22, the second leg 23 and the third leg 27 has a respective protrusion 6 that is intended for coming into contact with an end of the busbar 4. The protrusion 6 of the first leg 22, the second leg 23 and the third leg 27 each allow for tolerance compensation if a busbar 4 (like the busbar shown in FIG. 16) is arranged between the first leg 22, the second leg 23 and the third leg 27. The effect described in conjunction with FIG. 16 will come true for each individual protrusion 6 shown in FIG. 17a.

It should be mentioned that any (limited) rotations about a vertical axis in FIGS. 17a to 20 will be compensated also by an elastic response of the second leg 23 and the third leg 27 together with the already described functions of the protrusion 6. This is illustrated in FIG. 18 which is a view of the clamp 11 from above (in relation to FIG. 17a). It shows that the second and third legs 23 and 27 are not aligned any more but have elastically reacted to a rotation of busbar 4 around a rotation axis perpendicular to the drawing in FIG. 18. It can be seen that the protrusions 6 have a rolling function in this reaction.

The electrode 5 shown in FIGS. 17a to 20 has a connection end 7 that is connected, for example welded, to a further section to contact to a battery cell or a parallel arrangement of battery cells.

The respective bridges 21 and/or the respective first legs 22 and/or the respective second legs 23 and/or the respective third legs 27 are elastically deformable. These parts of the electrode 5 provide the clamp 11, which in the embodiments shown in FIGS. 17a to 20 has a third state, in which a reference part of the first leg 22 (for example the protrusion 6 of the first leg 22) is distanced from a reference part of the second leg 23 (for example the protrusion 6 of the second leg 23) by a third amount and whereby a reference part of the first leg 22 (for example the protrusion 6 of the first leg 22) is distanced from a reference part of the third leg 27 (for example the protrusion 6 of the third leg 23) by a third amount. In some embodiments, the third state is identical to the first state such that the third amount and the first amount are the same. The clamp 11 also has a second state, in which the same part of the first leg 22 is distanced from the same part of the second leg 23 by a second amount that is different from the first amount and in which the same part of the first leg 22 is distanced from the same part of the third leg 27 by a second amount.

FIG. 20 shows that in the embodiment shown in FIGS. 17a to 20, a spring clamp 18 is provided. The spring clamp 18 can be used to introduce forces that move the clamp 11 from the second state into the first state into parts of the clamp 11. In particular, spring clamp 18 can be designed in view of its mechanical function and elastic properties and clamp 11, on the other hand, can be designed more in view of its electrical functions such as Ohmic resistances of the clamp as such and of the contact to be made. For example, clamp 11 could be made of well conducting material, for example copper, and spring clamp 18 of spring steel. Similar ideas apply to other embodiments as well.

Claims

1. A battery unit for a high current power supply system, the battery unit comprising an electrode comprising a clamp; the clamp comprising a transition section connecting a first leg, arranged at one end of the transition section;to a second leg arranged at the opposite end of the transition section wherein the transition section and/or the first leg and/or the second leg being elastically deformable;wherein the clamp has a first state where a reference part of the first leg is distanced from a reference part of the second leg by a first amount;wherein the clamp has a second state where the reference part of the first leg is distanced from the reference part of the second leg by a second amount that is different from the first amount; andwherein the transition section and/or the first leg and/or the second leg is further elastically deformed in the second state than in the first state.

2. The battery unit according to claim 1, wherein the first leg and/or the second leg comprises a protrusion, the protrusion being convex in two non-parallel sectional planes.

3. The battery unit according to claim 1, wherein the battery unit further comprises a third leg; wherein the third leg is also arranged at the opposite side of the transition section on a side of the transition section on which the second leg is also arranged; wherein the third leg is elastically deformable; wherein;the clamp has a third state, in which the reference part of the first leg is distanced from a reference part of the third leg by a third amount; wherein;the clamp has a fourth state, in which the reference part of the first leg is distanced from the reference part of the third leg by a fourth amount that is different from the third amount; and whereinthe transition section and/or the first leg and/or the third leg is further elastically deformed in the fourth state than in the third state.

4. The battery unit according to claim 1, wherein the battery unit further comprises a third leg, and whereby a further transition section is provided that connects the first leg to the third leg; wherein the first leg is arranged at one end of the further transition section and the third leg is arranged at the opposite end of the further transition section; whereinthe further transition section and/or the third leg is elastically deformable;wherein the clamp has a third state, in which the reference part of the first leg is distanced from a reference part of the third leg by a third amount;wherein the clamp has a fourth state, in which the reference part of the first leg is distanced from the reference part of the third leg by a fourth amount that is different from the third amount; and whereinthe further transition section and/or the first leg and/or the third leg are further elastically deformed in the fourth state than in the third state.

5. The battery unit according to claim 3, wherein the third leg comprises a protrusion, and wherein the protrusion is rounded and convex in two non-parallel sectional planes.

6. The battery unit according to claim 4, wherein the transition section and the further transition section are arranged parallel to each other.

7. The battery unit according to claim 1, wherein the battery unit comprises a spring clamp that at least partially grips around the clamp.

8. The battery unit according to claim 1, wherein the battery unit comprises a connector suitable to hold a busbar in contact with the clamp.

9. The battery unit according to claim 8, wherein a connector casing defines an opening configured such that a part of the busbar may be inserted into the connector casing via the opening, a clearance being arranged in the connector casing between the opening and a space between the first leg and the second leg.

10. A system comprising a battery unit according to claim 1, the system further comprising a busbar held in contact with the clamp of the battery unit.

11. The system according to claim 10, wherein the system comprises a further battery unit, the busbar being held in contact with the clamp of the further battery unit.

12. A system with a battery unit according to claim 1, wherein the battery unit and a further battery unit are arranged inside a casing of the system, the battery unit and the further battery unit being electrically connected to each other, and the further battery unit being connected to the electrode of the battery unit.

13. A method for assembly of a system according to claim 11, wherein the method comprises the steps of: providing a first battery unit,a second battery unit,and a busbar; andbringing a part of the busbar into contact with the clamp of the first battery unit and bringing a further part of the busbar into contact with the clamp of the second battery unit.