Classifications

• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01F—MAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
  • H01F38/00—Adaptations of transformers or inductances for specific applications or functions
  • H01F38/14—Inductive couplings
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01F—MAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
  • H01F27/00—Details of transformers or inductances, in general
  • H01F27/28—Coils; Windings; Conductive connections
  • H01F27/2804—Printed windings
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
  • H01M10/00—Secondary cells; Manufacture thereof
  • H01M10/42—Methods or arrangements for servicing or maintenance of secondary cells or secondary half-cells
  • H01M10/46—Accumulators structurally combined with charging apparatus
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
  • H01M50/00—Constructional details or processes of manufacture of the non-active parts of electrochemical cells other than fuel cells, e.g. hybrid cells
  • H01M50/20—Mountings; Secondary casings or frames; Racks, modules or packs; Suspension devices; Shock absorbers; Transport or carrying devices; Holders
  • H01M50/204—Racks, modules or packs for multiple batteries or multiple cells
  • H01M50/207—Racks, modules or packs for multiple batteries or multiple cells characterised by their shape
  • H01M50/213—Racks, modules or packs for multiple batteries or multiple cells characterised by their shape adapted for cells having curved cross-section, e.g. round or elliptic
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01F—MAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
  • H01F27/00—Details of transformers or inductances, in general
  • H01F27/28—Coils; Windings; Conductive connections
  • H01F27/2804—Printed windings
  • H01F2027/2809—Printed windings on stacked layers
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01F—MAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
  • H01F27/00—Details of transformers or inductances, in general
  • H01F27/34—Special means for preventing or reducing unwanted electric or magnetic effects, e.g. no-load losses, reactive currents, harmonics, oscillations, leakage fields
  • H01F2027/348—Preventing eddy currents
• • Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
  • Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
  • Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
  • Y02E60/00—Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
  • Y02E60/10—Energy storage using batteries

Definitions

• Inductive charging coil devices in particular handheld power inductor charging coil devices, having at least one coil unit are already known.
• the invention is based on an inductive charging coil device, in particular a handheld power inductor coil device, with at least one coil unit.
• the coil unit has at least one conductor with at least two main sections arranged in parallel in terms of line technology.
• a "coil unit” is to be understood as meaning in particular a unit which has at least one conductor loop with at least one winding formed by a conductor
• the coil unit is intended to transmit and / or preferably to receive electrical energy in at least one operating state
• the coil unit may be provided to support the at least one conductor loop.
• the inductive charging coil device may be provided to send energy to another inductive charging coil device Convert alternating current into an alternating magnetic field and / or vice versa.
• the alternating field has a frequency of 10 - 500 kHz, more preferably 100 - 120 kHz.
• a "hand tool induction charging coil device” should be understood to mean, in particular, a hand-held electrical appliance, such as, in particular, a power drill, in a hand-held power tool , a hammer drill, a saw, a planer, a screwdriver, a milling cutter, a grinder, an angle grinder and / or a
• a "main cross-section” is to be understood as meaning, in particular, regions of a conductor cross-section formed of an electrically conductive material with thickness increased in relation to regions between the main cross-sections
• a "thickness” in this context shall be understood to mean, in particular, a direction perpendicular to a spacing of main cross-sections
• an "enlarged" thickness is to be understood as meaning at least an increase of 50%, preferably 75%, particularly preferably more than 90%
• the main cross-sections are arranged in a line-parallel fashion
• the main cross-sections extend along a predominant part of a conductor length , particularly preferably along more than 90% of the conductor length.
• circuit technology parallel should be understood to mean in particular circuit-connected in parallel.
• the main cross sections of the conductor preferably have a common winding sense.
• the main cross sections of the conductor in the region of the conductor loop are arranged next to one another in relation to a winding radius about a winding axis.
• a material cross-section of the conductor required for a desired electrical resistance of the coil unit can be advantageously divided between the main cross-sections arranged in parallel in terms of line technology.
• a material cross section of a main cross section of the conductor in particular in the direction of the winding radius, may be smaller than a material cross section of a main cross section of a coil unit whose winding is formed by a conductor having a single main cross section.
• One surface of the conductor may face a conductor with a single main cross-section. cut be increased at the same total cross-section.
• a "surface of the conductor” should be understood as meaning, in particular, a surface of the conductive material of the conductor.Ewurrent losses in the conductor can be effectively reduced.A skin effect can be smaller for a conductor having a plurality of main cross sections. In this context, it should be understood, in particular, that with a conductor through which a high-frequency alternating current flows, a current density at the surface of the conductor is higher than in its interior. Electrical losses can be reduced. Heating of the coil unit can be reduced. An efficiency can be advantageously increased.
• the conductor has at least three main cross sections. Cross-sectional areas of the individual main cross-sections can be further reduced. The surface of the conductor can be further increased. Electric losses can be particularly low. An efficiency of the induction charging coil device can be particularly high.
• adjacent main cross-sections of the at least one conductor are arranged in contact and / or adjacent main cross-sections of the at least one conductor are connected to one another.
• "touching” is to be understood in particular as meaning that surfaces of the main cross-sections touch between adjacent main cross-sections in such a way that there is electrical contact between the main cross-sections in particular cohesive connection.
• the cohesive connection preferably has a reduced thickness compared with the thickness of the main cross section, in particular a reduced thickness of more than 50%, preferably more than 80%.
• the main cross sections can be arranged in a particularly space-saving manner.
• the conductor can have a particularly large overall cross-section.
• the main cross sections in the region of the conductor loop are preferably electrically insulated from one another.
• "insulated” is to be understood as meaning preferably a resistance between the main cross sections in the region of the conductor loop of more than 1 kilohm
• Main cross sections may be arranged at a distance from each other. The entire surface of the conductor can be particularly large. A current flow between the main cross sections can be avoided. Losses of the inductive charging coil device can be further reduced.
• an insulator is proposed, which is at least partially disposed between adjacent main cross sections of the conductor.
• An "insulator” is to be understood as meaning, in particular, a material having an electrical conductivity of less than 10 -3 S / m, preferably less than 10 -8 S / m (Siemens / meter)
• the insulator may comprise an air layer and / or at least A current flow between main cross sections of the conductor can be effectively reduced in the region of the winding, losses of the inductive charging coil device can be further reduced.
• the coil unit is at least partially formed by conductor tracks of at least one conductor layer of a printed circuit board.
• the printed circuit board preferably has at least one electrically insulating carrier layer and at least one conductor layer adhering to the carrier layer.
• the carrier layer may be formed by a flexible film or preferably a rigid material, such as a plastic, in particular a fiber-reinforced plastic. Other materials known to those skilled in the art are also possible.
• the conductor layer may preferably be formed by a copper alloy or another electrically conductive material, in particular a metal.
• conductor tracks of the conductor layer form main cross sections of the conductor of at least one winding of the coil unit.
• Winding the winding of the coil unit can be omitted.
• a winding carrier to be wound around the windings of the coil unit may be omitted.
• the carrier layer of the circuit board can support the windings.
• the carrier layer of the printed circuit board can fulfill the function of a winding carrier of the coil unit.
• a thickness of the coil unit in the direction of the winding axis can be particularly small.
• the coil unit can be produced particularly inexpensively.
• the carrier layer of the printed circuit board can support the main cross sections of the conductor particularly well.
• the coil unit can be particularly robust. Particularly advantageously, the coil unit is arranged at least partially on two conductor layers of the printed circuit board. In particular, the coil unit can be arranged at least partially on two opposite sides of the at least one carrier layer of the printed circuit board.
• conductor layers which form conductor loops of the coil unit can be arranged on the opposite sides of the carrier layer. It is also possible that a plurality of conductor layers are arranged separated by an insulating layer on one side of a carrier layer.
• the printed circuit board has a multilayer structure with a plurality of carrier layers. On the carrier layers, conductor layers can be arranged on one side and / or preferably on both sides. It is also possible for a plurality of conductor layers to be arranged separately on one side of a carrier layer by insulation layers. There may be a particularly large number of conductor layers available.
• the conductor loops of the coil unit can be arranged particularly flexibly.
• the inductive charging coil device can be a particularly large number
• the conductor loops can in sum have a particularly large number of turns. It is proposed that the coil unit has at least three conductor loops.
• the conductor loops are preferably arranged on at least three sides of carrier layers of the printed circuit board.
• a double-layer printed circuit board with two carrier layers can have conductor loops on three sides of the carrier layers, and conductor tracks which are provided for further applications, in particular for receiving and / or connecting electrical and / or electronic components, on a fourth side.
• the conductor loops preferably have windings with the same winding sense.
• a "winding sense” should be understood to mean, in particular, a winding direction about the winding axis
• the electromagnetically conductive conductor loops of the coil unit can at least substantially match the properties of a coil with a continuous conductor loop
• Winding number which corresponds to the sum of the winding numbers of the conductor loops of the coil unit have.
• a number of windings required for the coil unit can advantageously be arranged on a plurality of conductor layers.
• a number of turns of the individual conductor loops can be reduced.
• the printed circuit board has at least one leadthrough through which at least one connecting conductor of the coil unit is made.
• the connection conductor can connect at least two conductor loops of the coil unit.
• the connecting conductor is guided through a recess at least one carrier layer of the printed circuit board.
• the conductor loops can be effectively electrically connected.
• a winding number of two conductor loops in sum is odd.
• the number of turns of two conductor loops arranged on a carrier layer is, in sum, odd.
• a winding can be divided between the two conductor loops.
• the two conductor loops can each have half a winding.
• the two connected by the connecting conductor ends of the conductor loops can advantageously be arranged spatially separated from the other, free ends of the conductor loops.
• the ends connected by the connecting conductor can be arranged on the printed circuit board relative to the winding axis with respect to the other ends.
• connection areas of the coil unit is to be understood as meaning areas which receive connection means which are intended to electrically contact the conductor loops
• connection areas are connected to the free ends of the conductor loops
• Conductor loops are understood, which form the beginning and / or end of the coil formed by the conductor loops of the coil unit.
• contact means such as, in particular, plug connectors and / or soldering surfaces can be provided in the connection regions.
• Connection means can be arranged particularly advantageous.
• a construction of the inductive charging coil device can be particularly simple.
• the inductive charging coil device has an electronic unit and / or a core unit and a contacting unit for contacting the coil unit and that the contacting unit is guided through a recess of the electronic unit and / or the core unit.
• an "electronic unit” is to be understood in particular to mean a device which has at least one electrical and / or electronic component,
• the electronic unit may comprise a printed circuit board is intended to bundle an electromagnetic field.
• the core unit may be at least partially formed by a magnetic material.
• a magnetic material is in this context in particular a
• ferrimagnetic in particular soft magnetic material understood.
• Magnetic material may be formed by a ferrite material.
• a "ferrite” is to be understood as meaning, in particular, a material which comprises at least 70%, advantageously at least 80%, preferably at least 90%, of iron oxide (Fe 2 O 3 and / or Fe 3 O 4 ).
• the magnetic material preferably has a permeability number ⁇ greater than 100, preferably greater than 1000, particularly preferably greater than 5000.
• the core unit may be a sintered component.
• the elements may preferably be formed by a ceramic material, in particular ferromagnetic material, whereby advantageously a particularly high degree of efficiency in energy transmission can be achieved a "ceramic" material is understood to be an inorganic polycrystalline material, which was produced by a sintering process.
• the core unit is at least partially disposed between the electronic unit and the coil unit.
• a "contacting unit” is to be understood as meaning preferably a device which is provided for a releasable contacting of the coil unit,
• the contacting unit can be designed as a plug connection with two
• the connector may preferably have a plug and a coupling.
• alternative embodiments of the contacting unit are also conceivable, in particular leads which make contact by means of a solder connection.
• one of the connector elements, preferably the plug fixed to the Be connected coil unit.
• the plug connection element can be soldered to the coil unit.
• the other connector elements preferably the plug, fixed to the Be connected coil unit.
• Plug connection element to be connected to the electronics unit preferably soldered.
• the further plug connection element can be designed as a coupling.
• Plug-in elements at least to a large extent within the
• Recesses of the core unit and / or the electronic unit to be arranged By “to a large extent”, more than 50%, preferably more than 60%, particularly preferably more than 80%, of an outer volume of the plug-in connection should be understood in this connection
• Inductive charging coil device can be particularly compact.
• the inductive charging coil device may be particularly thin in a thickness direction in the direction of a winding axis.
• a device having the inductive charging coil device can be particularly compact.
• An assembly of the inductive charging coil device can be particularly simple.
• Mounting movement form the contacting of the coil unit with the electronic unit.
• the coil unit has at least one winding with a different winding shape from a circular shape.
• a “winding form” should be understood to mean, in particular, the form of an averaged winding path of the windings of a conductor loop.
• “Deviating from a circular shape” should in this context be understood to mean a winding form deviating from a circular form, in which a length of the winding track is at least by 10% longer, preferably by more than 20% longer, more preferably by more than 30% longer than a circumference of a largest inscribed in the winding path circle.
• the winding form can be adapted to a shape of a construction space of a housing in which the inductive charging coil device is arranged.
• the inductive charging coil device can have a construction space especially good use.
• the inductive charging coil device can be particularly powerful.
• An electrical power of the coil unit can be particularly high. It is proposed that at least one conductor loop has a winding shape at least approximated to a rectangle.
• a rectangle at least approximated in this context is to be understood in particular that the winding path along more than 50%, preferably more than 75%, of its circumference of a rectangle by less than 10%, preferably less than 5%, based on a Corners of the winding form of the conductor loop may preferably have a radius, and particularly preferably the winding form of the conductor loop may be approximated to a square
• the inductive charging coil device may be particularly flexible
• the coil unit can emit and / or receive particularly well electromagnetic fields that deviate from circular symmetry.
• An efficiency and / or a performance of the inductive charging coil device can be dependent on an orientation Efficiency and / or performance of the inductive charging coil device may be adjustable.
• a coil storage unit is proposed, which is intended to rotatably support the at least one coil unit about at least one axis.
• the reel storage unit is provided for rotatably supporting the at least one reel unit about its winding axis. It is also possible for the reel storage unit to rotatably support the inductive charging reel.
• the coil storage unit can rotatably support the inductive charging coil device on a housing unit, in particular on a housing unit of a hand-held power tool or of a hand tool battery pack.
• An orientation of the coil unit can be advantageously adapted to an orientation of a coil unit of a further inductive charging coil device.
• the orientation of the coil unit can be changed while a handheld power tool and / or a hand tool battery pack, which have the coil unit, remain stationary.
• an alignment unit is proposed, which is intended to align the coil unit in an orientation about at least one axis.
• the alignment unit is preferably provided for aligning the coil unit in its orientation about its winding axis.
• the alignment unit may in particular be a device which at least partially carries out an automatic alignment of the coil unit.
• the alignment can be made according to a defined orientation, in particular according to an orientation of another inductive charging coil device.
• the orientation may be dependent on a performance of the inductive charging coil device, in particular the orientation may be such that an electrical power and / or an efficiency of the inductive charging coil device reaches a desired value, in particular is maximized.
• the alignment unit may in particular contain at least one active alignment means such as, in particular, an actuator.
• the alignment unit may include mechanical alignment means, in particular means for alignment by means of a positive connection, such as guides and / or scenes.
• the coil unit can be aligned particularly effectively advantageous.
• the inductive charging coil device has a display unit which is provided in at least one operating state to signal a user a quality of an orientation of the coil unit about the axis.
• the display unit can be provided to signal the user the quality of an orientation of the coil unit about its axis of winding.
• the display unit may in particular have signal means such as
• Lamps and / or LEDs that indicate the quality of the orientation in color and / or symbolic.
• the display unit can signal a good and / or sufficient orientation, in particular by a green signal color and / or a pictogram.
• the display unit may indicate inaccurate and / or in particular unsuitable alignment by means of a yellow or red signal color and / or a pictogram.
• Graphical and / or numerical displays are also conceivable which indicate, for example, the quality of the orientation as a percentage of an optimal alignment. It is also conceivable to provide acoustic displays and further forms of an indication of the orientation that appear appropriate to the person skilled in the art.
• an electronics unit and / or cell unit and a shielding unit arranged between the coil unit and the electronics unit and / or cell unit which has an electrically conductive material layer with a projection surface which, when projected in the direction of the winding axis of the coil unit, at least substantially the electronics unit and / or cell unit covered.
• An "electronic unit” is to be understood in this context, in particular a device having at least one electrical and / or electronic component.
• the electronic unit may have a printed circuit board.
• the charging electronics can be part of the electronics unit.
• a "cell unit” is to be understood as meaning, in particular, an energy storage unit which has at least one rechargeable battery cell, which is provided in particular for electrochemical storage of electrical energy.
• Other types of rechargeable battery cells known to those skilled in the art are also conceivable.
• shielding in this case is understood to mean, in particular, a reduction of an alternating electromagnetic field propagating in the direction of the coil unit to be shielded in the area of the shielded subassembly become.
• the alternating electromagnetic field is preferably reduced by at least 50%, particularly preferably by at least 80%.
• the alternating electromagnetic field is caused by operation of the inductive charging coil device.
• a "projection surface” is to be understood to mean, in particular, an area of a shadow cast by a body in a parallel projection in
• Projection direction are understood.
• at least substantially overlapping is to be understood in this context in particular that the projection of the shielding in the projection direction an outer contour of the electronics unit and / or cell unit, preferably the electronics unit and cell unit, at least 90%, preferably more than 95%, especially
• the electrically conductive material layer can shield the electromagnetic field in particular by reflecting it and throwing it back in.
• the electronic unit and / or cell unit to be shielded can be protected from the electromagnetic field, an influence of the electromagnetic field on the electronic unit and / or cell unit can be reduced.
• Leakage currents which are caused in the electronics unit and / or cell unit by the electromagnetic alternating field, can be reduced. Heating of the electronics unit and / or cell unit by leakage currents can be reduced.
• Damage to the electronics unit and / or cell unit and / or reduced service life of the electronics unit and / or cell unit and / or malfunction of the electronics unit and / or cell unit due to influences of the alternating electromagnetic field on the electronics unit and / or cell unit can be avoided.
• An efficiency of the inductive charging coil device may be increased.
• a core unit is proposed, the projection surface of which, when projected in the direction of a winding axis of the coil unit, at least substantially covers the electronic unit and / or cell unit.
• the core unit can preferably concentrate field lines of the alternating electromagnetic field and concentrate in the region of the coil unit and / or steer it in the direction of a further inductive charging coil device.
• An energy contained in the electromagnetic alternating field can be at least partially absorbed by the coil unit and amplify an electric current.
• the core unit can shield the electronic unit and / or cell unit from the electromagnetic field as a shielding unit.
• the core unit can have the stated advantages of a shielding unit.
• the hand tool device can be formed by a hand tool machine, a hand tool pack, a hand tool case or by a hand tool packer.
• the hand tool device may have the stated advantages of the inductive charging coil device.
• FIG. 1 is a schematic representation of a coil unit of a Induktivlade- coil device
• FIG. 2 shows a schematic illustration of a hand tool battery charger and a hand tool battery pack with induction coil units according to the invention
• FIG. 3 shows a schematic representation of a section of the inductive charging coil device of the hand tool battery pack
• FIG. 4 shows a schematic illustration of a hand tool battery pack with an inductive charging coil device in a second exemplary embodiment
• FIG. 5 shows a schematic illustration of a coil unit of an inductive charging coil device in a third exemplary embodiment
• FIG. 6 is a schematic sectional view of a hand tool battery pack with the inductive charging coil device of the third embodiment and a hand tool battery charger with a further inductive charging coil device,
• FIG. 7 is a schematic sectional view of the coil unit of the hand tool battery pack in a second sectional plane
• FIG. 9 shows a schematic representation of a system with two inductive charging coil devices in a fourth exemplary embodiment
• FIG. 10 shows a schematic representation of a hand tool battery pack with an inductive charging coil device in a fifth exemplary embodiment.
• 1 1 is a schematic sectional view of a coil unit of a Induktivladespulenvorraum in a sixth embodiment
• FIG. 1 shows a coil unit 12a of an inductive charging coil device 10a with two conductor loops 60a, each with a spiral winding 34a.
• the coil unit 12a is formed by a rectangular printed circuit board 24a (FIG. 2).
• the printed circuit board 24a has conductor layers 22a which form printed conductors 20a.
• the conductor tracks 20a form windings 34a of the coil unit 12a (FIG. 2).
• the conductor layers 22a are arranged on two sides 26a of a carrier layer 28a of the printed circuit board 24a.
• the carrier layer 28a of the printed circuit board 24a thus fulfills the function of a winding carrier of the windings 34a of the coil unit 12a.
• the windings 34a each have a conductor 14a with three main cross sections 16a.
• the main cross sections 16a are arranged in parallel in line technology and are formed by the conductor tracks 20a. Gaps 62a in the direction of a radius about a winding axis 46a between the adjacent main cross sections 16a form insulators 18a.
• the main cross sections 16a are additionally insulated and sealed with a paint layer not shown.
• the main cross sections 16a terminate after 414 windings about the winding axis 46a in a terminal region 66a, relative to the winding axis 46a, on opposite sides of the printed circuit board 24a. Through a passage 30a of the printed circuit board 24a, a connecting conductor 32a connected to the main cross sections 16a is guided.
• connection conductor 32a connects the windings 34a on the two sides 26a of the circuit board 24a.
• the windings 34a have the same winding sense about the winding axis 46a.
• Both conductor loops 60a have the same winding number of 414 windings, so that the coil unit 12a has an odd winding number of 9. Since each conductor loop 60a has half a winding and the leadthrough 30a faces the connection region 66a, both windings 34a end in the region of the connection region 66a arranged on the two sides 26a of the printed circuit board 24a.
• the conductor loop 60a has, when the main cross-sections 16a of a high-frequency
• the inductive charging coil device 10a is part of a hand tool device 58a (FIG. 2).
• the hand tool device 58a is designed as a hand tool battery pack 82a.
• a housing unit 84a is a cell unit 38a arranged, which is intended to provide a hand tool with energy.
• the inductive charging coil device 10a is provided for wireless power transmission for a charging operation of the cell unit 38a.
• the inductive charging coil device 10a is disposed between the cell unit 38a and a housing wall 86a of the housing unit 84a. Starting from the housing wall 86a in the direction of the cell unit 38a, first the coil unit 12a, a core unit 48a and an electronic unit 36a follow.
• the electronic unit 36a is connected to the cell unit 38a by means of a connection conductor 68a, and includes charging electronics provided to charge the cell unit 38a.
• a contacting unit 52a (FIG. 3) guided through recesses 54a, 56a of the electronic unit 36a and the core unit 48a connects the electronic unit 36a and the coil unit 12a.
• the contacting unit 52a has a plug 100a with connection pins 98a which are guided through recesses 102a through the coil unit 12a and contact connection regions 96a.
• a bush 104a protrudes into the recess 54a of the electronic unit 36a. In an operative state of the inductive charging coil device 10a, the plug 100a projects into the socket 104a.
• Plug 100a and socket 104a form the contacting unit 52a.
• a shielding unit 40a Arranged on the side of the electronics unit 36a facing the core unit 48a is a shielding unit 40a formed by a conductive material layer 42a, which has a projection surface 44a which, when projected in the direction of the winding axis 46a of the coil unit 12a, covers the electronic unit 36a and the cell unit 38a.
• An alternating magnetic field in the region of the coil unit 12a is largely reflected by the shielding unit 40a in the direction of the coil unit 12a, so that a field strength in the area of the cell unit 38a and the electronic unit 36a is reduced.
• the hand tool battery pack 82a is placed on a hand tool apparatus 58a 'designed as a hand tool battery charger 88a', which has an analogous built-up inductive charging coil apparatus 10a '.
• the hand tool battery charger 88a ' has a power supply 70a'. If the hand tool battery charger 88a 'is supplied with power, the inductive charging coil apparatus 10a' is flowed through by a high-frequency alternating current of 100 kHz, which is generated by a charging electronics arranged on an electronic unit 36a '.
• a coil insert unit 12a ' an alternating magnetic field is generated, which is bundled by a core unit 48a' and emitted essentially in the direction of the inductive charging coil apparatus 10a.
• a current is induced with which the cell unit 38a can be charged.
• FIG. 4 shows a hand tool battery pack 82b with a coil unit 12b of an inductive charging coil apparatus 10b in a second exemplary embodiment.
• the inductive charging coil device 10b differs from the inductive charging coil device 10a of the first embodiment, in particular, in that a core unit 48b is trough-shaped and has a projection surface
• the core unit 48b surrounds the electronics unit 36b completely around the winding axis 46b and partially surrounds the cell unit 38b.
• the core unit 48b concentrates an alternating magnetic field incident on the core unit 48b from the direction of the coil unit 12b, and directs it toward the core unit 48b.
• a field strength of the alternating magnetic field is particularly low.
• the electronic unit 36b and the cell unit 38b can be protected from influence of the alternating magnetic field.
• the coil unit 12b is formed by a printed circuit board 24b with printed conductors 20b.
• FIG. 5 shows a schematic illustration of a coil unit 12c of an inductive charging coil device 10c in a third exemplary embodiment.
• the spools- Unit 12c has two conductor loops 60c with windings 34c with a shape deviating from a circular shape, a square with rounded corners 1 18c approximate winding shape.
• the windings 34c of the conductor loops 60c are formed by conductor tracks 20c, which are formed by conductor layers 22c (FIG. 6) of a square printed circuit board 24c.
• the conductor layers 22c are arranged on two opposite sides 26c of a carrier layer 28c of the circuit board 24c.
• the windings 34c each have a conductor 14c which, in order to reduce eddy current losses, has the three main cross sections 16c arranged in parallel in line technology, which are formed by the conductor tracks 20c.
• the main cross sections 16c are insulated and sealed with a paint layer not shown.
• the main cross sections 16c terminate after 514 windings about a winding axis 46c relative to a winding axis 46c, opposite sides of the printed circuit board 24c.
• Terminal areas 96c are arranged congruently in the thickness direction 94c of the printed circuit board 24c.
• a connecting conductor 32c connected to the main cross sections 16c is guided.
• the connection conductor 32c connects ends of the windings 34c on both sides 26c of the circuit board 24c.
• the windings 34c of the conductor loops 60c have the same winding sense around the winding axis 46c. Both conductor loops 60c have the same winding number of 514 windings, so that the coil unit 12c in sum has an odd number of turns of 1 1.
• the inductive charging coil device 10c is part of a hand tool device 58c (FIG. 6).
• the hand tool device 58c is designed as a hand tool battery pack 82c.
• a cell unit 38c is arranged, which is intended to provide power to a hand tool.
• the shape of the printed circuit board 24c and the winding form of the conductor loops 60c are adapted to a base surface of a housing wall 86c of the housing unit 84c which is perpendicular to the winding axis 46c and make use of the base area by more than 94%.
• the inductive charging coil device 10c is provided for wireless power transmission for a charging operation of the cell unit 38c.
• the inductive charging coil device 10c is disposed between the cell unit 38c and the housing wall 86c of the housing unit 84c. Starting from the housing wall 86c in the direction of the cell unit 38c, first the coil unit 12c, a core unit 48c and an electronic unit 36c follow.
• the electronic unit 36c is connected to the cell unit 38c by means of a connection conductor 68c, and includes a charging electronics provided to charge the cell unit 38c.
• a contacting unit 52c (FIG. 7) guided through recesses 54c, 56c of the electronic unit 36c and the core unit 48c connects the electronic unit 36c and the coil unit 12c.
• the contacting unit 52c has a plug 100c with connection pins 98c, which are guided through recesses 102c through the coil unit 12c and contact the connection regions 96c.
• a bush 104c protrudes into the recess 54c of the electronic unit 36c.
• Plug 100c and socket 104c form the contacting unit 52c.
• a shielding unit 40c formed by a conductive material layer 42c, which has a projection surface 44c which, when projected in the direction of the winding axis 46c of the coil unit 12c, covers the electronic unit 36c and the cell unit 38c.
• An alternating magnetic field in the region of the coil unit 12c is largely reflected by the shielding unit 40c in the direction of the coil unit 12c, so that a field strength in the area of the cell unit 38c and the electronic unit 36c is reduced.
• the hand tool battery pack 82c is placed on a hand tool device 58'c designed as a hand tool battery charger 88'c, which has an analogous built-up inductive charging coil device 10'c.
• the hand tool battery charger 88'c has a power supply 70'c. If the hand tool battery charger 88 'c is supplied with power, a coil unit 12' c is traversed by a high-frequency alternating current of 100 kHz, which is generated by a charging electronics arranged on an electronic unit 36 'c. In the coil unit 12'c, an alternating magnetic field is generated, which is generated by a core unit 48'c.
• the core unit 48c and 48'c have for this purpose in a matrix material cast on, formed of a ferrite material weichmagneti- see core elements.
• a current with which the cell unit 38c can be charged is induced.
• Conductor loops 60'c of the inductive charging coil device 10'c completely cover the conductor loops 60c of the inductive charging coil device 10c irrespective of their orientation around the winding axis 46c by making a smallest winding of the conductor loop 60'c in its entire circumference around a winding axis
• the inductive charging coil device 10c has a smallest radius smaller than a smallest radius of the conductor loop 60c, and a largest winding of the conductor loop 60'c in its entire circumference around the winding axis 46'c has a largest radius larger than a largest radius the conductor loop 60c.
• the orientation of the inductive charging coil device 10c about the winding axis 46c with respect to the inductive charging coil device 10'c has little effect on energy transfer.
• FIG. 8 shows examples of further alternative winding forms which can be used instead of the square-shaped winding form of the coil unit 12c.
• the person skilled in the art will select a suitable winding shape according to a geometry of a housing unit.
• Figure 8-I shows a conductor loop 60c 'having a winding shape approximating a rectangle.
• Figure 8-II shows a conductor loop 60c "having a winding shape approximating two semicircles with two straight side edges
• Figure 8-III shows a conductor loop
• Fig. 8-IV shows a conductor loop 60c "" with a winding shape approximated to a trapezoid.
• FIG. 9 shows a system with two hand tool machines battery 82d and hand tool battery charger 88'd with hand tool devices 58d and 58'd arranged inside their coil units 12d and 12'd having inductive charging coil devices 10d and 10'd in a fourth exemplary embodiment.
• the hand tool devices 58d and 58'd differ from the third embodiment, in particular, by an alignment unit 1 14d, which is provided to connect a coil unit 12d of the inductive charging device.
• coil device 10d in an orientation to align at least one axis 1 12d.
• the hand tool battery pack 82d has guide grooves 120d with which it is inserted into a guide rail 122'd of the hand tool battery charger 88'd for loading a cell unit of the hand tool devices 58d (not illustrated here).
• the guide grooves 120d and the guide rails 122'd form the alignment unit 1 14d, which is intended to align the inductive charging coil devices 10d and 10'd in an orientation about the axis 1 12d formed by winding axes 46d and 46'd.
• the alignment unit 1 14d also defines the orientation of the hand tool battery pack 82d relative to the hand tool battery charger 88'd by the further rotational degrees of freedom as well as two translatory degrees of freedom.
• the coil units 12d, 12'd have, similarly to the third embodiment, windings 34d, 34'd formed by conductor loops 60d, 60'd, as well as electronic units 36d, 36'd.
• FIG. 10 shows a hand tool device 58e designed as a hand tool battery pack 82e and having an inductive charging coil device 10e in a fifth exemplary embodiment.
• the inductive charging coil device 10e differs from the inductive charging coil device 10c of the third exemplary embodiment in particular by a coil storage unit 110e, which is provided to rotatably rotate the inductive charging coil device 10d with a coil unit 12e about an axis 112e formed as a winding axis 46e of windings 60e formed by conductor loops 60e to store.
• the inductive charging coil device 10e has a coil housing 124e in which the coil unit 12e and a core unit 48e are arranged.
• the coil housing 124e is rotatably mounted with the coil bearing unit 110e on a housing unit 84e of the hand tool battery pack 82e so as to be rotatable about the winding axis 46e of the coil unit 12e.
• a locking element 126e serves to fix the coil housing 124e in a basic position.
• a display unit 1 16e is arranged on the hand tool battery pack 82e, which signals a quality of an orientation of the coil unit 12e about the axis 1 12e to a user in a loading operation.
• the display unit 1 16e thus forms an alignment unit 1 14e.
• the display unit 1 16e displays the quality in steps between 0% and 100%. The user can unlock the locking element 126e and rotate the spool housing 124e until optimum performance is achieved. If the hand tool battery pack 82e is used for drove a hand tool used, displays the display unit 1 16e the user alternatively a state of charge of a cell unit 38e of the hand tool battery pack 82e.
• FIG. 11 shows a coil unit 12f of an inductive charging coil device 10f in a sixth exemplary embodiment.
• the coil unit 12f is formed by a printed circuit board 24f.
• the inductive charging coil device 10f differs from the inductive charging coil device 10a of the first embodiment in particular in that the printed circuit board 24f has a multilayer structure with two carrier layers 28f.
• the printed circuit board 24f has three conductor loops 60f arranged on the sides 26f of the carrier layers 28f. Two conductor loops 60f are arranged on outer sides 106f forming sides 26f of the carrier layers 28f of the printed circuit board 24f, a third conductor loop 60f is arranged between two inner sides 108f forming sides 26f of the carrier layers 28f.
• the three conductor loops 60f are formed by three conductor layers 22f of the circuit board 24f. Two feedthroughs not shown in detail here with connecting conductors connect the conductor loops 60f. A plug 100f is provided for contacting the coil unit 12f as in the previous embodiment.
• the coil unit 12f has a larger number of conductor loops 60f compared to the first embodiment, and thus may have in total a larger number of windings 34f about a winding axis 46f.
• the coil unit 12f is used in the inductive charging coil apparatus 10f analogous to the first embodiment.
• FIG. 12 shows further possible main cross sections 16g'-g "'of conductors 14g'-g”' of further coil units (not shown in detail in this example) of further inductive charging coil devices.
• the main cross sections 16g'-g "'shown can be used analogously in all exemplary embodiments
• the main cross sections 16g'-g"' are formed by conductor tracks 20g'-g "'of a printed circuit board 24g'-g"' and have a trapezoidal shape , wherein a trapezoidal base 90g'-g "'is oriented towards a carrier layer 28g'-g"' of the circuit board 24g'-g "'.
• Figure 12-1 shows a conductor 14g 'whose main cross-sections 16g' are spaced apart in the direction of a radius about a winding axis 46g 'of windings 34g' at a distance from gaps 62g '.
• the main cross sections 16g ' are completely separated along the gaps 62g 'and electrically insulated from each other. This corresponds to the conductors 14a, 14b shown in the first and second embodiments.
• Figure 12-11 shows a conductor 14g "whose main cross sections 16g" in contrast to the main cross sections 16g 'are arranged touching.
• the main cross sections 16g 'are in each case in contact with outer edges of their trapezoid base 90g.
• the main cross sections 16g can thus be arranged in a particularly compact manner. In the direction of a radius about a winding axis 46g "adjacent main cross sections 16g", there are no common material cross sections along windings 34g ", therefore no or only small current flows take place between adjacent main cross sections 16g".
• the conductor 14g has an especially compact arrangement of the main cross sections 16g" with an identical overall cross section.
• FIG. 12-111 shows a conductor 14g '' 'whose trapezoidal main cross sections 16g' 'are arranged so close in the direction of a radius about a winding axis 46g' '' of windings 34g '' that they are in a connecting region 92g '' at their trapezoidal bases 90g '. "are interconnected. Due to the skin effect, which forces high-frequency currents to the conductor surface, current flows between the adjacent main cross-sections 16g '' are low in the case of high-frequency currents.
• the conductor 14g ''' has an even more compact arrangement of the main cross-sections 16g' '' with an identical overall cross-section ,

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• Chemical & Material Sciences (AREA)
• Chemical Kinetics & Catalysis (AREA)
• Electrochemistry (AREA)
• General Chemical & Material Sciences (AREA)
• Manufacturing & Machinery (AREA)
• Charge And Discharge Circuits For Batteries Or The Like (AREA)
• Secondary Cells (AREA)

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• 2013
  • 2013-12-17 DE DE201310226228 patent/DE102013226228A1/de not_active Withdrawn
  • 2013-12-18 EP EP13811907.8A patent/EP2936514A1/de not_active Withdrawn
  • 2013-12-18 WO PCT/EP2013/077148 patent/WO2014096039A1/de active Application Filing
  • 2013-12-18 US US14/653,110 patent/US20150340153A1/en not_active Abandoned
  • 2013-12-18 CN CN201380067477.5A patent/CN104871266A/zh active Pending

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