WO2015055536A1 - Energy storage unit for a handheld power tool - Google Patents

Abstract

The invention relates to an energy storage unit for a handheld power tool, comprising a housing (14a; 14b; 14c) which has a flat housing base side (20a; 20b; 20c) and comprising at least one electric contact means (16a, 18a; 16b; 18b; 16c; 18c) which exits the housing on the housing base side (20a; 20b; 20c). The contact means (16a, 18a; 16b, 18b; 16c, 18c) has a contact plane at least in a mounted state, said contact plane being offset to the housing base side (20a; 20b; 20c) in a parallel manner.

Description

 description

Energy storage unit for a hand tool

State of the art

There has already been proposed an energy storage unit for a handheld power tool having a housing which has a flat housing base side and at least one electrical contact means which emerges on the housing base side.

DISCLOSURE OF THE INVENTION The invention is based on an energy storage unit for a hand-held power tool, with a housing having a flat housing base side, and with at least one electrical contact means, which on the

Housing base exits. It is proposed that the contact means be mounted at least in one

State has a contacting plane, which is arranged parallel to the housing base side.

As a result, a void volume can be avoided and an existing space can be used particularly advantageously. In this context, an "energy storage unit" is to be understood as meaning, in particular, an electrical energy storage unit, preferably an electrochemical energy storage unit, preferably a rechargeable energy storage unit, for example an accumulator cell, in particular a lithium polymer cell. that extends at least in one direction along a main extension direction of the housing of the energy storage unit. Preferably, the housing base side is formed as a largest side of the housing, and is for example formed as the base side of a cuboid, which defines a basic shape of the housing. The housing base defines a housing base plane at least in an area where the contact means exits. In this context, a "contact means" should be understood as meaning, in particular, a means which is provided to electrically connect one electrode of the energy storage unit to at least one connection contact for the energy storage unit outside the housing the at least one connection contact has a profile which is arranged parallel to the housing base plane in an area in which the contact means exits, and preferably at least immediately adjacent to the housing base plane and particularly preferably in the housing base plane In this context, a "contacting plane" is to be understood as meaning, in particular, a plane in which the at least one contact means is located st is disposed in a region of the terminal. Preferably, a course of the

Contact means in the region of the terminal fixed the contacting level. The term "provided" is to be understood to mean in particular specially designed and / or equipped.Assuming that an object is intended for a specific function should in particular mean that the object fulfills this specific function in at least one application and / or operating state and / or executes.

It is also proposed that the at least one electrical contact means is bent into the contacting plane at least in an assembled state. As a result, a particularly efficient contacting step of the energy storage unit can be achieved during assembly and a short assembly time. Preferably, the profile of the contact means has an orientation which changes along the course by 180 degrees or in the sum of 0 degrees. In an advantageous embodiment, the at least one electrical contact means is at least twice bent at least in an assembled state. As a result, a required installation space can be further reduced and a particularly compact arrangement of the energy storage unit can be achieved. In this context, the term "two-fold curved" should be understood in particular to mean that the profile of the contact means has at least two arcs which are preferably separated from one another by a straight section of the profile or which have different directions of curvature In this way, a particularly advantageous arrangement of the contact means for an efficient contacting step can be achieved. "S-shaped" should in this context be understood to mean in particular that the contact means successively in two opposite Directions by an equal angle, preferably with a counter curvature, is bent.

It is also proposed that the housing has a housing center, relative to an extension perpendicular to the housing base side, which at least in an assembled state spatially between the housing base side and the

Contacting level is arranged. This can be achieved particularly efficiently that a required space is small. It can be achieved a particularly simple installation of the energy storage unit. In this context, a "housing center" should be understood as meaning, in particular, a planar area which has a central location between the housing base side and one of the housing areas

Housing base opposite housing cover side arranged level includes. Preferably, the housing center has an extent perpendicular to the housing base side of 10%, preferably of 20% and particularly preferably of 30% based on a total extension of the housing of the energy storage unit in the direction perpendicular to the housing base.

In an advantageous embodiment, the energy storage unit has at least one mounting unit, which is provided to fix the at least one contact means in the contacting plane. As a result, a particularly time-saving installation of the energy storage cell can be achieved. Under a "Mon In this context, it should be understood in particular to mean a unit which is intended to be connected to the energy storage unit in an assembly step Preferably, the assembly unit is provided to store the energy storage unit in an assembled state and / or to arrange it relative to further energy storage units ,

It is further proposed that the mounting unit has at least one guide surface for the at least one contact means, which is provided for the deformation of the contact means in the contacting plane. As a result, the at least one contact means can be deformed particularly time-saving in an assembly step in the contacting plane, in which the energy storage unit is connected to the mounting unit. An additional assembly step for the deformation and / or arrangement of the contact means can be omitted. It is conceivable that the mounting unit has a guide channel with a side on which the guide surface is arranged.

It is also proposed that the energy storage unit comprises at least one further contact means, which has a further contacting level. As a result, the contact means in a mounted state at a defined distance from each other. It can be a particularly easy and time-saving

Contacting be achieved. In this context, a "further contact means" should be understood as meaning, in particular, a means which is designed analogously to the first contact means and is intended to electrically connect a further electrode of the energy storage unit to at least one further connection contact outside the housing Contact means different electrical polarity and are formed as a positive and as a negative contact means Preferably, the further contacting plane is arranged parallel offset to the housing base side.

In an advantageous manner, the contacting planes of the at least two contact means enclose the housing base side between them. As a result, a particularly secure and error-free contacting can be achieved. In this context, the phrase "enclose the housing base between themselves" should be understood in particular to mean that the contacting NEN are arranged on different sides of the housing base side and spaced from each other.

Further, a cordless device for a hand tool with at least two energy storage units is proposed, each having a housing, each having a flat housing base side, and in each case at least one electrical contact means, which exits respectively on the housing base side, wherein the contact means at least in an assembled state Have Kontaktie- tion level, which is arranged parallel to the housing base in each case. As a result, a particularly compact, space-saving battery device can be provided. It can be achieved a high level of comfort for a user. In this context, a "rechargeable battery device" should be understood to mean, in particular, a device which is provided for supplying energy to a machine, in particular a hand-held power tool.Preferably, the rechargeable battery device has a dimensionally stable housing, which is provided for a separable electrical and mechanical connection to the machine It is also conceivable that the battery device is firmly integrated in a housing of the machine.

In an advantageous embodiment, the contact means of the at least two energy storage units of the cordless device have a common contacting level. As a result, the energy storage units can be coupled to one another mechanically and / or electrically in a particularly simple manner. It is conceivable that in each case positive contact means of the energy storage units on the one hand and each negative contact means of the energy storage units on the other hand have a common contacting level. It is also conceivable that the contact means as a whole have a common contacting plane.

It is also proposed that the battery device has a connection unit for electrical contacting of the contact means of the energy storage units, which is formed at least partially integral with mounting units of the at least two energy storage units. As a result, an electrical contact can be advantageously used for a mechanical connection and efficient assembly of a plurality of energy storage units can be achieved. It can for the energy storage unit gentle joining methods, such For example, resistance welding, are used. Damage to the energy storage units, for example, by heat, can be avoided and a reject rate can be reduced. It can be achieved a particularly simple installation. Manufacturing errors can be avoided and a short production time can be achieved. By "in one piece" is meant, in particular, at least materially bonded, for example by a welding process, an adhesion process, an injection process and / or another process that appears expedient to the person skilled in the art, and / or advantageously shaped in one piece, for example by a production from a casting and / or by a production in a single or multi-component injection molding process and advantageously from a single blank.

In an advantageous embodiment, the connection unit has at least one conductor carrier, which is passed through energy storage units, at least in an assembled state. As a result, a required space can be further reduced. It can be achieved a particularly flexible arrangement of energy storage units in the battery device. The conductor carrier can form surface contact points together with the contact elements, for example in a welding process. It can be formed particularly robust contact points, which are particularly insensitive to vibration, for example. The contact points can be arranged in an assembled state between the energy storage units and particularly well protected against external influences, such as conductive particles such as metal shavings. In this context, the term "between" should be understood to mean, in particular, spatially between two energy storage units adjacent in a stacking direction The stacking direction is preferably arranged perpendicular to the housing base sides of the energy storage units It is conceivable for the assembly unit to comprise positioning elements, such as spacers, ribs, supports or Having clips, whereby a particularly simple and efficient arrangement of the conductor carrier can be achieved.

Furthermore, a handheld power tool having at least one rechargeable battery device is proposed, which comprises at least two energy storage units, each having a housing which has a flat housing base side, and in each case at least one electrical contact means, which emerges on the housing base side, have, wherein the contact means have at least in a mounted state a contacting plane, which is arranged in parallel to the housing base side in parallel.

The energy storage unit according to the invention should not be limited to the application and embodiment described above. In particular, the energy storage unit according to the invention can have a number deviating from a number of individual elements, components and units specified herein for fulfilling a mode of operation described herein.

drawing

Further advantages emerge from the following description of the drawing. In the drawing, three embodiments of the invention are shown. The drawing, the description and the claims contain numerous features in combination. The person skilled in the art will expediently also consider the features individually and combine them into meaningful further combinations.

Show it:

1 is a schematic exploded view of a battery device with an energy storage unit according to the invention,

 2 shows a perspective view of the energy storage unit, FIG. 3 shows a section along a longitudinal axis of the energy storage unit,

 4 the energy storage unit with contact means, which are arranged in a contacting plane,

 5 shows an arrangement of energy storage units in a mounting unit,

 6 shows an energy storage unit of a further exemplary embodiment,

 Fig. 7, the energy storage unit, with the contact means in a

Contacting level are arranged, 8 shows an arrangement of energy storage units which are connected to a connection unit,

 9 is a schematic view of a larger number of energy storage units connected to the connection unit.

 10 shows the energy storage units with the connection unit in a further assembly step,

 11 is a view in the direction of end faces of the energy storage units in an assembled state,

 12 shows an energy storage unit of a further exemplary embodiment with contact means which are each arranged in a contacting plane

 Fig. 13 and a schematic view of an arrangement of energy storage units in an assembled state.

Description of the embodiments

FIG. 1 shows a rechargeable battery device 26a for a handheld power tool. The battery device 26a is provided for a power supply of the hand tool. It is conceivable that the battery device 26a is provided for the power supply of another electric machine. The battery device 26a has a plurality of energy storage units 10a, 12a.

FIGS. 2 to 5 show an energy storage unit 10a of the battery device 26a. The energy storage units 10a, 12a of the battery device are designed to be analogous to one another, which is why only one of the energy storage units 10a is described in more detail below in the following. The energy storage unit 10a is intended to receive electrical energy in a charging process, to store the energy and, if necessary, to deliver it in an operating state of the handheld power tool. In the present embodiment, the energy storage unit 10a is formed as a lithium polymer cell and has a rated voltage of 3.6 volts. The energy storage unit 10a has a housing 14a with a flat, rectangular housing base side 20a. The energy storage unit 10a has a cuboid base body 30a with a length 32a, a width 34a and a height 36a. The housing 14a has a housing cover side 38a lying opposite the housing base side 20a and parallel to the housing cover side 38a

 Housing base 20 a is arranged. It is conceivable for the main body 30a to have another basic shape which appears reasonable to the person skilled in the art, and for the housing base 20a to be triangular or trapezoidal, for example. The height 36a is arranged in a direction perpendicular to the casing base 20a. The width 34a and the length 32a are in a plane of

Housing base 20 a arranged. In the present embodiment, the length 32a is greater than the width 34a and the width 34a greater than the height 36a. The main body 30a has two end faces 42a, which are each delimited by edges in the direction of the height 36a and the width 34a of the housing 14a. A first of the end faces 42a is visible in FIGS. 2 and 3.

The main body 30a has two longitudinal sides which are bounded respectively by edges in the direction of the length 32a and the height 36a of the housing 14a.

The casing 14a has a casing film 40a formed of plastic-coated aluminum foil. It is conceivable that the casing film 40a is formed of another suitable material. The main body 30a has four base side edges on the housing base side 20a. At three of the basic side edges, the housing 14a extends in each case in a fold 44a, 46a, 48a, ie the housing 14a has three folds 44a, 46a, 48a. It is conceivable that the housing 14a has four folds. It is also conceivable that the housing 14a has a different basic shape, for example a non-angular basic shape and correspondingly fewer folds. The housing 14a preferably has at least one fold 46a. The energy storage unit 10a comprises two electrical contact means 16a, 18a, which emerge on the housing base side 20a. The contact means 16a, 18a are formed as sheet metal strips and have a strip pattern. The contact means 16a, 18a emerge on one end face edge 50a, which is arranged on the first end face 42a of the main body 30a, on one of the folds 44a. The fold 44a, on which the contact means 16a, 18a emerge, forms in each case in the region of the contact means 16a, 18a of a layer structure comprising at least one layer 52a of the sheath foil 40a, each having a metal strip of the contact means 16a, 18a and a further layer 54a of the sheath foil 40a. The contact means 16a, 18a are connected to a terminal of the energy storage unit

10a provided. The energy storage unit 10a comprises at least two electrodes, one of which is electrically connected in each case to an interior of the housing 14a, each with a contact means 16a, 18a. The strip pattern is arranged in an interior of the housing 14a in a region of the base side edge at which the contact means 16a, 18a emerge, parallel to the housing base side 20a.

The contact means 16a, 18a are provided for electrical contacting of the energy storage unit 10a and have different electrical

Polations on. A first of the contact means 16a has a positive polarity in a charged state of the energy storage unit 10a. Another of the contact means 18a has a negative polarity in the charged state. In an operating state, energy flows out of the energy storage unit 10a by means of the contact means 18a.

In an initial state for assembly, the fold 46a, on which the contact means 18a emerge, is arranged parallel to the housing base side 20a (FIG. 2). The contact means 18a are arranged in an extension of the housing base side 20a and each have a maximum of the main body 30a remote free end 56a, 58a with an orientation. The further folds 46a, 48a are in the direction of the housing cover side 38a perpendicular to the

Housing base 20a bent away from the housing base side 20a.

In a mounted state, the fold 44a, on which the electrical contact means 18a emerge from the main body 30a, is bent away from the housing base side 20a with the contact means 16a, 18a in the direction of the housing cover 38a, perpendicular to the housing base 20a. The contact means 16a, 18a extend along the first end face 42a at least substantially parallel to the end face 42a. The contact means 16a, 18a are bent in a further course on the further front side edge 60a, which faces the front side edge 50a, on which the contact means 16a, 18a, away from the base body 30a perpendicular to the end face 42a of the end face 42a away. In the assembled state, the contact means 16a, 18a at the front side edge 50a, where they emerge from the main body 30a, each have an arc, at which the strip profile forms an angle of about 90 degrees. The contact means 16a, 18a have at the other front edge edge 60a each have a further arc, at which the strip profile forms an angle of about 90 degrees. The bows each have a magnitude same angle. The sheets have opposite directions along the course of the strip. The orientation of the free ends 56a, 58a is obtained compared to the initial state.

The electrical contact means 16a, 18a have, in an assembled state, a contacting plane which is arranged parallel to the housing base side 20a of the energy storage unit 10a. The electrical contact means 16a, 18a are bent in the assembled state in the contacting plane.

The contact means 16a, 18a are bent twice in the mounted state. The electrical contact means 16a, 18a are bent in the assembled state S-shaped and have two oppositely directed curvatures of the same amount. The bends each have an amount of about 90 degrees. The contact means 16a, 18a extend in a region between the

Curvatures perpendicular to the housing base 20a. It is conceivable that contact means 16a, 18a each have two curvatures of an equal amount, which is less than 90 degrees. The housing 14a has, with respect to an extension perpendicular to the

Housing base 20a, a housing center 22a, which is arranged at least in an assembled state spatially between the housing base side 20a and the contacting plane. The contacting plane is arranged on an opposite side of the housing center 22a on the housing base side 20a. The contact means 16a, 18a pass through in an assembled state

Housing center 22a therethrough.

The energy storage unit 10a has a mounting unit which is provided to fix the at least one contact means 16a, 18a in the contacting plane. The mounting unit comprises an angle element 62a, which has two vertical has plate-shaped legs 64a, 66a arranged at right angles to each other, which are connected to one another at a vertex edge 68a of the angle element 62a. The angle element 62a is formed of a plastic. A first of the legs 64a forms a bearing surface for the energy storage unit 10a. Another of the legs 66a each has a passage 70a, 72a for the

Contact means 16a, 18a on. The bushings 70a, 72a are slit-shaped. A main extension direction of the bushings 70a, 72a is arranged parallel to the apex edge 68a of the angle element 62a. In an assembled state, the contact means 16a, 18a are each passed through the further leg 66a of the angle element 62a. The other leg

66a is intended to fix the contact means 16a, 18a in the contacting plane.

The energy storage units 10a, 12a are arranged in layers in the present embodiment. Each layer has two energy storage units 10a, 12a. It is conceivable that the layer has a larger number of energy storage units 10a, 12a or only consists of an energy storage unit 10a, 12a. In each case one of the longitudinal sides of the main body 30a of an energy storage unit 10a, 12a faces one of the longitudinal sides of the main body 30a of an adjacent energy storage unit 10a, 12a of the layer. The end faces 42a and the housing base sides 20a of the energy storage units 10a, 12a of the layer each lie in a common plane. The contact means 16a, 18a of the energy storage unit 10a, 12a of a pair have a common contacting plane. The front side edges 50a of the energy storage units 10a, 12a of the layer where the contact means 16a, 18a emerge are arranged on a same side of the layer. The mounting units of the energy storage units 10a, 12a of the group are integrally formed with each other as an angle member 62a in the present embodiment. The bushings 70a, 72a for the contact means 16a, 18a of the energy storage units 10a, 12a of a same layer are equidistant from the apex edge 68a of the angled element 62a. Figure 1 shows schematically the structure of the battery device 26a. The battery device 26a has several layers of energy storage units 10a, 12a. The housing cover sides 38a and the housing base sides 20a of the energy storage units of adjacent layers are each facing each other. The Akkuvorrichtung 26 a comprises an intermediate layer member 74 a, which is arranged in an assembled state between the first leg 66 a of the angle member 62 a and the energy storage units 10 a, 12 a. The rechargeable battery device 26a comprises a housing 76a, which is provided to store the energy storage units 10a, 12a and to couple the rechargeable battery device 26a to the handheld power tool not shown in more detail. In the present embodiment, the battery device 26a is provided to be inserted into a corresponding receptacle of the power tool and it has an insertion direction. The housing 76a is formed substantially of plastic and includes a bottom member 78a and a lid member 80a. The housing 76a has a cuboid basic shape. The lid member 80a is formed stepwise on an upper side. In the present embodiment, the housing 76a at a step transition on two guide elements 82a, which are each formed as a groove in the insertion direction. The housing 76a further comprises a locking element 84a for locking with the hand tool. The locking element 84a is designed as a latching element, which protrudes in a locking position over a surface of the cover element 80a. The battery device 26a has an operating element 86a for unlocking the locking element 84a. The battery device 26a comprises a connection unit with a conductor carrier

28a. The connection unit is provided for electrically connecting the energy storage units 10a, 12a by means of series and / or parallel circuits. The battery device 26a has solder joints, at which the conductor carrier 28a is electrically connected to the contact means 16a, 18a of the energy storage units 10a, 12a.

The battery device 26a has a contact unit 88a. The contact unit 88a is provided for electrical connection with the hand tool. The rechargeable battery device 26a comprises two connection conductors 90a, 92a, which in an assembled state electrically connect the connection unit to the connec- tor. connect clock unit 88a. The connection conductors 90a, 92a have a different electrical polarity in a charged state of the energy storage units 10a, 12a. It is conceivable that the housing 76a is designed in a different manner, which makes sense to a person skilled in the art for a coupling with the electric machine, and accordingly has alternative guide elements and / or locking elements and / or contact units.

FIGS. 6 to 13 show further exemplary embodiments of the invention. The following descriptions and the drawings are essentially limited to the differences between the exemplary embodiments, with reference in principle also to the drawings and / or the description of the other exemplary embodiments, in particular those relating to identically named components, in particular with regard to components having the same reference numbers Figures 1 to 5, can be referenced. To distinguish the embodiments of the letter a is the reference numerals of the embodiment in Figures 1 to

5 adjusted. In the embodiments of Figures 6 to 11, the letter a is replaced by the letter b and in the embodiments of Figures 12 and 13, the letter a is replaced by the letter c. FIGS. 6 to 11 show an energy storage unit 10b of a handheld power tool. The energy storage unit 10b is formed analogously to the preceding embodiment and provided to receive electrical energy in a charging process, to store the energy and deliver it when needed in an operating state of the power tool. The energy storage unit 10b has a housing 14b. The housing 14b is designed analogously to the preceding exemplary embodiment and comprises a main body 30b with a housing base side 20b and four base side edges. At three of the basic side edges, the housing 14b extends in each case in a fold 44b, 46b, 48b, ie the housing 14b has three folds 44b, 46b, 48b. The energy storage unit 10b comprises two electrical contact means 16b, 18b, which emerge on the housing base side 20b. The contact means 16b, 18b are formed analogously to the preceding embodiment and exit at one of the folds 44b. In an initial state for assembly, the fold 44b, on which the contact means 16b, 18b exit, is arranged parallel to the housing base side 20b (FIG. 6). The contact means 16b, 18b are in an extension of

Housing base side 20b arranged and each have a maximum of the main body 30b remote free end 56b, 58b with an orientation. The further folds 46b, 48b are bent in the direction of a housing cover side 38b perpendicular to the housing base side 20b away from the housing base side 20b.

The fold 44b, at which the electrical contact means 16b, 18b emerge from the base body 30b, is in an assembled state with the contact means

16b, 18b in the direction of the housing cover 38b perpendicular to the

Housing base side 20b bent away from the housing base side 20b. The contact means 16b, 18b extend along a first end face 42b parallel to the end face 42b (FIG. 7). In contrast to the preceding exemplary embodiment, the contact means 16b, 18b are bent in a further course on a front side edge 60b, which is opposite to a front side edge 50b, on which the contact means 16b, 18b emerge, in the direction of the main body 30b, i. They each cover an area of the housing cover side 38b. The contact means 16b, 18b have at the front side edge 50b, on which they emerge from the main body 30b, in each case an arc, at which the strip profile forms an angle of about 90 degrees. The contact means 16b, 18b each have a further arc on the further front side edge 60b, which lies opposite the front side edge 50b, where the strip profile forms an angle of approximately 90 degrees. The sheets each have an equal angle. In contrast to the preceding embodiment, the sheets have a same direction along the strip path. The orientation of the free ends 56b, 58b is rotated 180 degrees compared to the initial state.

In an assembled state, the electrical contact means 16b, 18b have a contacting plane which is arranged parallel to the housing base 20b of the energy storage unit 10b. The electrical contact means 16b, 18b are bent in the assembled state in the contacting plane. The contact means 16b, 18b are bent twice in the mounted state. The electrical contact means 16b, 18b are bent in the assembled state U-shaped and have two mutually rectified curvatures of the same amount. The bends each have an amount of about 90 degrees. The contact means 16b, 18b extend in a region between the curvatures at least substantially perpendicular to the housing base side 20b. It is conceivable that the contact means 16b, 18b each have two curvatures of different magnitude with a total of about 180 degrees.

The housing 14b has, relative to an extension perpendicular to the housing base side 20b, a housing center, which is arranged at least in an assembled state spatially between the housing base side 20b and the contacting plane. The contacting level is on one of the

Housing base 20b opposite side of the housing center arranged. The contact means 16b, 18b pass through the housing center in an assembled state.

The energy storage unit 10b has a mounting unit which is provided to fix the at least one contact means 16b, 18b in the contacting plane. The contact means 16b, 18b are connected in an assembled state with the free end 56b, 58b fixed to the mounting unit. The mounting unit has two contact points 94b, 96b, which are each assigned to one of the contact means 16b, 18b and to which the contact means 16b, 18b are respectively fixedly connected to the mounting unit. The contact means 16b, 18b are welded to the mounting unit at the contact points 94b, 96b. The assembly unit has a planar design and at least in the region of the contact points

94b, 96b arranged parallel to the housing cover 38b side.

FIGS. 8 to 11 show the energy storage unit 10b and further analog energy storage units 12b of a group of energy storage units 12b for a cordless device for a handheld power tool. The

Battery device has a plurality of energy storage units 10b, 12b. The energy storage units 10b, 12b are arranged in layers analogous to the preceding embodiment. Each layer has two energy storage units 10b, 12b. It is conceivable that the layer has a larger number of energy storage units 10b, 12b or only one Energy storage unit 10b exists. The housing bases 20b of the energy storage units 10b, 12b of the layer are each arranged in a same plane. In each case one of the longitudinal sides of the main body 30b of an energy storage unit 10b faces one of the longitudinal sides of the main body 30b of an adjacent energy storage unit 10b of the layer. The front ends

42b and the housing base sides 20b of the energy storage units 10b, 12b of the layer each lie in a common plane. The contact means 16b, 18b of the energy storage units 10b, 12b of a pair have a common contacting plane. The front side edges 50b of the energy storage units 10b, 12b of the layer on which the contact means 16b, 18b exit are arranged on the same side of the layer. The battery device has several layers of energy storage units 10b, 12b. The housing cover sides 38b and the housing base sides 20b of the energy storage units 10b, 12b of adjacent layers are respectively facing each other.

The rechargeable battery device comprises a connection unit for an electrical contacting of the contact means 16b, 18b of the energy storage units 10b, 12b, which is formed at least partially in one piece with the mounting units of the energy storage units 10b, 12b. In the present exemplary embodiment, the connection unit has a conductor carrier 28b, which is designed as a flexible printed circuit board. The conductor carrier 28b is provided to electrically connect the energy storage units 10b, 12b to each other. The conductor carrier 28b is strip-shaped and has a strip direction. The conductor carrier 28b has two linear conductors 98b, 100b, which are arranged at least in the region of a layer parallel to each other and parallel to the strip direction.

The conductors 98b, 100b may also be arranged differently depending on the requirements of an interconnection of the energy storage units 10b, 12b. The conductors 98b, 100b are formed, for example, as metal strips. The conductors 98b, 100b are associated with different electrical poles and at the contact points 94b, 96b of the mounting units according to their polarity and the

Polarity of the contact means 16b, 18b electrically connected to one of the contact means 16b, 18b of the energy storage units 10b, 12b. The contact points 94b, 96b are arranged, with respect to one direction, perpendicular to the strip direction, spatially between the conductors 98b, 100b. The conductor carrier 28b has electrical connecting webs 102b, 104b, which the contact points 94b, 96b each connect to one of the conductors 98b, 100b in response to the polarity of the contact means 16b, 18b connected to the pad 94b, 96b, and are arranged spatially between the pads 94b, 96b and the respective conductor 98b, 100b. It is also conceivable that the contact points 94b, 96b are formed directly by the conductors 98b, 100b and the contact means 16b, 18b and the conductors 98b, 100b are widened, for example in the region of the contact points 94b, 96b. The contact points 94b, 96b, unlike the present embodiment, depending on the polarity of the respectively connected contact means 16b, 18b offset from one another.

In an assembly step, the energy storage units 10b, 12b are connected at the contact points 94b, 96b to the conductor carrier 28b. Of the

Housing cover side 38b of the energy storage units 10b, 12b ago seen, is the conductor support 28b on the contact means 16b, 18b (Figure 8). Of the

Seen on the housing base side 20b of the energy storage units 10b, 12b, the conductor carrier 28b is below the contact means 16b, 18b (FIG. 9). It is also conceivable that the conductor carrier 28b is arranged above the contact means 16b, 18b, viewed from the housing base side 20b, or that the contact means 16b, 18b are arranged on different sides of the conductor carrier 28b. The energy storage units 10b, 12b are rotated in a further assembly step in each case by an axis extending in the region of the end face 42b axis by 180 degrees. In this case, the contact means 16b, 18b are bent and come into contact with the housing cover 38b. The contact means 16b, 18b are located on the housing cover side 38b (Figure 10).

The battery device has a stack of energy storage units 10b, 12b. In the stack, the energy storage units of different layers are arranged offset in a stacking direction perpendicular to the housing base sides 20b of the energy storage units 10b, 12b. The conductor carrier 28b is adjacent in an assembled state between two energy storage units

Layers passed. The conductor carrier 28b forms straight sections 108b between energy storage units respectively adjacent in the stacking direction. Derived from the energy storage units, the stack has two longitudinal sides and two end faces 42b. The conductor carrier 28b forms on each of the two longitudinal sides a plurality of bent portions 106b, each one connect two straight sections 108b of the conductor support 28b. The bent portions 106 b are seen in the stacking direction of one of the end faces 42 b of the stack ago, arranged alternately in the stacking direction left and right on the longitudinal sides of the stack. The conductor carrier 28b has a meandering arrangement in an assembled state. Alternatively, it is conceivable that the connection unit has a plurality of conductor carriers which are each provided for contacting the contact means 16b, 18b of energy storage units 10b, 12b of a same layer and are each arranged between the layers. In the alternative embodiment, the conductor carriers are at least electrically connected to each other in a further assembly step. The rechargeable battery device comprises analogous to the preceding embodiment, a housing not shown in detail, which is intended to store the energy storage units and electrically and mechanically couple the rechargeable battery device with the power tool not shown.

FIGS. 12 and 13 show a further exemplary embodiment of an energy storage unit 10c of a handheld power tool. Analogous to the preceding exemplary embodiment, the energy storage unit 10c is provided to receive electrical energy in a charging process, to store the energy and, if necessary, to deliver it in an operating state of the handheld power tool. The energy storage unit 10c has a housing 14c. The housing 14c is analogous to the preceding embodiment and comprises a base body 30c with a housing base side 20c and four base side edges. At three of the base side edges, the housing 14c each terminates in a fold 44c, 46c, 48c, i. the housing 14c has three folds

44c, 46c, 48c. The energy storage unit 10c comprises two electrical contact means 16c, 18c, which emerge on the housing base side 20c. The contact means 16c, 18c are formed analogously to the preceding embodiment, emerge at one of the folds 44c and have different polarities, i. one of the contact means 16c is formed as a positive contact means 16c, and another one of the contact means 18c is formed as a negative contact means 18c.

In an initial state, the fold 44c at which the contact means 16c, 18c emerge is similar to the preceding embodiments, parallel to the Housing base 20c arranged. The contact means 16c, 18c are arranged in an extension of the housing base side 20c and each have a maximum of the main body 30c remote free end 56c, 58c with an orientation. The further folds 46c, 48c are bent in the direction of a housing cover side 38c perpendicular to the housing base side 20c away from the housing base side 20c.

In contrast to the preceding embodiments, the contact means 16c, 18c are bent differently in an assembled state (FIG. 12). The positive contact means 16c is at the fold 44c, where it exits, at an angle of about 45 degrees in a direction perpendicular to the

Housing base 20c bent in the direction of a housing center. At the free end 56c, the positive contact means 16c is bent at an angle of about 45 degrees in a direction perpendicular to the case base side 20c toward the case base side 20c.

The negative contact means 18c is at the fold 44c, where it exits, at an angle of about 45 degrees in a direction perpendicular to the

At the free end 58 c, the negative contact means 18 c is bent at an angle of about 45 degrees in a direction perpendicular to the housing base side 20 c in the direction of the housing base side 20 c. It is conceivable that the bending directions of the negative contact means 18c are interchanged with the bending directions of the positive contact means 16c. The contact means 16c, 18c each have an arc at the fold 44c, where they emerge, at which the course of the strip forms an angle of approximately 45 degrees. The contact means 16c, 18c each have a further arc at a free end 56c, 58c, at which the strip profile forms an angle of approximately 45 degrees. The bows each have a magnitude same angle. The sheets have opposite directions along the course of the strip. The orientation of the free ends 56c, 58c is obtained in comparison to the first assembly step.

In the assembled state, the electrical contact means 16c, 18c have a contacting plane which leads to the housing base side 20c of the energy supply. Chern unit 10c is arranged in parallel. The electrical contact means 16c, 18c are bent in the assembled state in the contacting plane. The contact means 16c, 18c are bent twice in the mounted state. The electrical contact means 16c, 18c are bent in the assembled state S-shaped and have two oppositely directed curvatures of the same amount. The bends each have an amount of about 45 degrees. The contact means 16c, 18c extend in an area between the bends at an angle of 45 degrees to the housing base side 20c. It is conceivable that the contact means 16c, 18c each have curvatures of an equal amount with a different value.

The energy storage unit 10c has a mounting unit which is provided to fix the at least one contact means 16c, 18c in the contacting plane. The mounting unit is designed as a guide template 110c in the form of a plastic frame. It is conceivable that the mounting unit is formed of a different insulating material. The mounting unit is provided to enclose the energy storage unit 10c in an assembled state at least from three sides. In the present exemplary embodiment, the assembly unit has a base side wall 112c, a longitudinal side wall 114c and an end wall 116c. The front side wall 116c has a larger wall thickness compared to the base side wall 112c and the longitudinal side wall 114c. In a mounted state, the bottom side wall 112c is in contact with the casing base side 20c of the energy storage unit 10c, and the longitudinal side wall 114c is in contact with one of the long sides of the energy storage unit 10c. The guide template 110c has a frame base edge 118c at which the end side wall 116c and the bottom side wall 112c are adjacent to each other. The guide template 110c has on the frame base edge 118c on a non-illustrated implementation for the negative contact means 18c. The implementation is slot-shaped. In an assembled state, the negative contact means 18c is passed through the passage.

The end wall 116c has two prism-shaped sections 120c, 122c. One of the sections 120c is associated with the positive contact means 16c. Another of the sections 122c is associated with the negative contact means 18c. The sections 120c, 122c have a common height which corresponds to the wall thickness of the end wall 116c. The sections 120c, 122c each have an outer side facing away from the energy storage unit 10c, which is parallel-displaced in a direction perpendicular to the base side wall 112c relative to a respectively opposite side. The outsides of the

Portions 120c, 122c are parallel displaced in directions opposite to each other in a direction perpendicular to the base sidewall 112c with respect to a respective opposite side. The sections 120c, 122c each have a sloping side which forms a guide surface for the contact means 16c, 18c respectively associated with the section 120c, 122c, which is provided for deforming the contact means 16c, 18c into the contacting plane. The sections 120c, 122c are further provided to fix respectively the associated contact means 16c, 18c in the contacting plane of the contact means 16c, 18c.

FIG. 13 shows the energy storage unit 10c and further analog energy storage units 12c of a group of energy storage units 10c, 12c for a cordless device for a handheld power tool. The battery device has a plurality of energy storage units 10c, 12c. The energy storage units 10c, 12c are arranged in layers analogous to the preceding embodiments. In the present exemplary embodiment, a layer has in each case two energy storage units 10c, 12c. It is conceivable that the layer has a larger number of energy storage units 10c, 12c or only consists of an energy storage unit 10c. In each case one of the longitudinal sides of the base body 30c of an energy storage unit 10c faces one of the longitudinal sides of the main body 30c of an adjacent energy storage unit 10c of the layer. End faces 42c and the housing base sides 20c of the energy storage units 10c, 12c of the layer each lie in a common plane. The contact means 16c, 18c of the energy storage unit 10c of a pair have a common contacting plane as a function of the polarity of the contact means 16c, 18c. The bottom edges of the energy storage units 10c, 12c of the layer where the contact means 16c, 18c exit are disposed on a same side of the layer. The mounting units of the energy storage units 10c, 12c of a layer are in the present embodiment integral with one another as a guide template 110c formed. The layers each have guide templates 110c which are designed analogously to one another, one of which is provided with a reference numeral in FIG. The battery device has several layers of energy storage units 10c,

12c with mutually parallel layer planes. The battery device has a stack arranged perpendicular to the stacking direction in which the layers are arranged successively. The housing cover sides 38c and the housing base sides 20c of the energy storage units 10c, 12c of adjacent layers are each facing each other. The prism-shaped

Portions 120c, 122c of the mounting units of mutually adjacent layers correspond to each other. The sections 120c, 122c respectively engage the guide template of the adjacent layer. Adjacent layers are interlocked by the respective guide templates 110c in an assembled state. The positive contact means 16c of the energy storage units 10c, 12c of a layer have a common contacting plane with the positive contact means of an adjacent layer in the stacking direction. The negative contact means 18c of the energy storage units 10c, 12 of the layer have a common contacting plane with the negative contact means of an adjacent layer opposite to the stacking direction.

The battery device comprises a connection unit with a conductor carrier 28c. The connection unit is provided for electrically connecting the energy storage units 10c, 12c. The conductor carriers 28c are strip-shaped and have passages 124c, 126c for the contact means 16c, 18c in a strip direction. Two of the passages 124c, 126c are provided in FIG. 13 by reference numerals. The conductor carriers 28c are each assigned to a layer. In a particularly simple manner, parallel connection of energy storage units 10c, 12c in adjacent stacks can be achieved. It is also conceivable that the conductor carriers 28c are provided for a series connection or for blocks of energy storage units 10c, 12c with another electrical arrangement which appears expedient to the person skilled in the art. The guide template 110c has on the Grundseitenwandung 112c analog to each other formed pin-shaped positioning elements 128c, one of which representatively in the figure 13 with a reference numeral verse-. hen is. The positioning elements 128c are provided to an arrangement of the conductor carrier 28c. It is conceivable that the guide template 110c further positioning elements in different form, which are provided for a particularly efficient assembly of the conductor carrier 28c. The battery device comprises analogous to the preceding embodiments, a non-illustrated dimensionally stable housing, which is intended to store the energy storage units and to couple the battery device with the power tool, not shown.

Claims

claims

An energy storage unit for a hand power tool, comprising a housing (14a; 14b; 14c) having a flat housing base (20a; 20b; 20c) and at least one electrical contact means (16a, 18a; 16b; 18b; 16c; 18c) , which exits on the housing base side (20a; 20b; 20c), characterized in that

 the contact means (16a, 18a; 16b, 18b; 16c, 18c), at least in a mounted state, has a contacting plane which corresponds to the

 Housing base (20a, 20b, 20c) is arranged in parallel.

2. Energy storage unit according to claim 1,

 characterized in that

 the at least one electrical contact means (16a, 18a; 16b, 18b; 16c, 18c) is bent into the contacting plane at least in an assembled state.

3. Energy storage unit according to claim 1 or 2,

 characterized in that

 the at least one electrical contact means (16a, 18a; 16b, 18b; 16c, 18c) is bent at least twice, at least in an assembled state.

4. Energy storage unit according to one of the preceding claims,

 characterized in that

the at least one electrical contact means (16a, 18a; 16c, 18c) is bent S-shaped at least in an assembled state. Energy storage unit according to one of the preceding claims, characterized in that

the housing (14a, 14b), relative to an extension perpendicular to the housing base side (20a; 20b), has a housing center (22a) which, at least in an assembled state, is spatially disposed between the housing

Housing base (20a, 20b) and the contacting plane is arranged.

Energy storage unit according to one of the preceding claims, characterized by

at least one mounting unit which is provided to fix the at least one contact means (16a, 18a; 16b, 18b; 16c, 18c) in the contacting plane.

Energy storage unit according to claim 6,

characterized in that

the mounting unit has at least one guide surface for the at least one contact means (16c, 18c) which is provided for deforming the contact means (16c, 18c) into the contacting plane.

Energy storage unit according to one of the preceding claims, characterized by

at least one further contact means (18c) having a further contacting plane.

Energy storage unit according to claim 8,

characterized in that

the contacting planes of the at least two contact means (16c, 18c) enclose the housing base side (20c) between them.

Battery device for a power tool with at least two energy storage units (10a, 12a, 10b, 12b, 10c, 12c) according to one of the preceding claims.

11. Battery device according to claim 10,

 characterized in that

 the contact means (16a, 18a, 16b, 18b) of the at least two energy storage units (10a, 12a, 10b, 12b) have a common contacting plane.

12. Battery device according to claim 11,

 marked by

 a connection unit for electrical contacting of the contact means (16b, 18b) of the energy storage units (10a, 12a, 10b, 12b), which is formed at least partially in one piece with mounting units of the at least two energy storage units (10b, 12b).

13. Battery device according to claim 12,

 characterized in that

 the connection unit has at least one conductor carrier (28b) which, at least in an assembled state, is guided between energy storage units (10b, 12b).

14. Hand tool with at least one battery device according to one of claims 10 to 13.