EP2450921A1 - Charger, receiving station and plug device for inductive transmission of electrical energy - Google Patents

Abstract

In a charging device (1) for inductive transmission of electrical energy and which is connectable to a power source (10), with a made of a magnetically conductive material core (2) which is rotationally symmetrical about a longitudinal axis (3) or its outer contour ( 4) has a constant or linearly increasing distance relative to the longitudinal axis (3) relative to a plane (22, 23, 24) aligned perpendicular to the longitudinal axis (3), with a coil (7) wound on the core (2) forming wire (6) of electrically conductive material through which current flows in the state of charge and a magnetic field, (32) is formed, and with a housing consisting of an electrically insulating material (31), through which the core (2) and the coil (7) are covered to the outside, the best possible transfer of energy take place and at the same time the charging device (1) should be designed as a coupling element. the core (2) is formed from at least two steps (5 ', 5 ", ... 5 n) such that the outer contour of the first step (5') is a greater distance from the longitudinal axis (3) of the core (2). as the outer contour of the second stage (5 ") and that the coil (7) of the second stage (5") is associated.

Description

The invention relates to a loading device according to the preamble of claim 1, to a receiving station according to the preamble of claim 7 and to a plug-in device according to the preamble of claim 12.

From the DE 19743860 C1 is to remove a device for the inductive transmission of electrical energy, which consists of a charging device and a receiving station in an electrically operated toothbrush. The receiving station is electrically connected to a battery or a rechargeable battery, through which the motor of the toothbrush is supplied with power. The receiving station is plugged into the charging device, so that the coils of the receiving station and the charging device are aligned with each other so that the magnetic field generated by the coil of the charging device affects the coil of the receiving station and thus inductively transmitted electrical energy. In fact, due to the iron cores and the electrical flux, the magnetic field radiates outward and is received by the coil of the receiving station, so that electrical energy is transmitted inductively from the coil of the charging device to the coil of the receiving station. This electrical energy is forwarded to the accumulators in the toothbrush and stored there.

A disadvantage of such known charging devices and receiving stations that form a common plug-in device, it has been found that a significant loss of efficiency occurs because the formation of the magnetic field for the inductive transmission of electrical energy is not positively influenced and defined three-dimensional. This may be sufficient for electrical appliances that have a low energy requirement and thus a low requirement for storing this energy, especially as such toothbrushes can often be charged in the loading device for a longer period of time, for example overnight.

However, should there be a need to charge electrical devices, such as electrically powered bicycles, scooters, lawn mowers or the like, within a shortest possible period of time while providing a fast charge cycle available, it is necessary that the efficiency for inductive transmission of electrical energy as high as possible.

In addition, it is necessary to make a distinction as to which electric devices are to be charged. The drive motor of a bicycle requires less stored electrical energy than the electric drive motor of a scooter. Therefore, there is also a need to provide a charging device by which more or less electrical energy can be transmitted inductively depending on the rechargeable batteries, thereby reducing the power consumption of the charging device.

From the US 6,268,785 B1 is to take a loading device whose outer contour is designed in the form of a truncated cone. On the loading device, a receiving station is pushed, the inner contour is adapted to the outer contour of the loading device. The charging and receiving device are used for inductive transmission of electrical energy and data. A coil forming a coil winding is wound onto the outer jacket of the charging device. Spaced to this first winding, a second coil is mounted, which is arranged in the region of the tip of the truncated cone.

In the receiving station two receiving coils are provided, which are aligned in the mounted state, ie in the plane formed by the two transmitting coils.

It is therefore an object of the invention to provide a charging device of the type mentioned, which has at least one, preferably a plurality, levels in which coils are arranged for the inductive transmission of electrical energy and which is also designed as a coupling element. In addition to be provided by the invention, a receiving station of the type mentioned, which is fixedly or detachably attached to an electrically operated device and which is connectable to the charging device, so that one or more windings in the form of coils of the receiving station in alignment with the respective Coil of the charger in the state of charge run and thus form coil pairs.

It is another object of the invention to provide a plug-in device of the type mentioned, consisting of a charging device and a receiving station, by means of which optionally different amounts of electrical energy can be transmitted inductively and at the same time the efficiency of the inductive energy transfer is high and no scattering losses due to undesirable Three-dimensional emissions of the magnetic field arise.

These objects are achieved according to the invention with respect to the loading device by the features of the characterizing part of claim 1, with respect to the receiving station by the features of the characterizing part of claim 7 and in terms of the connector by the features of the characterizing part of claim 12.

Further advantageous developments of the invention will become apparent from the dependent claims.

Characterized in that the core of the charging device is formed of at least two stages, is first advantageously achieved by the larger training of the first stage at which no coil is provided that the magnetic field, which is associated with the second adjacent thereto stage of the coil , is screened, because the first stage is based on the longitudinal axis of the core sized larger than the second stage and on the other hand, such a configured charging device can be used as a coupling element, because this is freely accessible from above and the outer contour of the charging device is suitable as a plug connection. The efficiency for inductive energy transmission is thus optimized because the magnetic field is deflected defined in a predetermined manner. Scattering losses are therefore minimized. Consequently, a further receiving coil, which is arranged in the magnetic field of the coil of the charging device, inductively absorb electrical energy and forward it to an accumulator.

It is particularly advantageous if the loading device is formed from at least two stages, where at least one coil is mounted and when each of the steps has a cross-sectionally L-shaped outer contour, which faces the coil, because this can on the one hand, the coils form a common or a separate magnetic field and on the other hand, the magnetic fields are three-dimensionally deflected structured in a predetermined manner by the L-shaped outer contour, so that in this way the efficiency for inductive energy transfer is high and leakage losses are minimized.

Since the coils of the charging device extend in different planes, which are arranged perpendicular to the longitudinal axis of the core of the charging device, and the receiving station has corresponding coil arrangements, differently configured receiving stations can be plugged onto the charging device, depending on the energy requirement that is required is to charge an electrical device associated with the receiving station. Namely, if the electrical appliance has an increased energy requirement, then several pairs of coils of the charging device and the receiving station are necessary and if the energy consumption of the charging electrical device should be lower, only a pair of coils of the charging device and the receiving station can be coupled in alignment with each other inductive energy transfer to accomplish, the remaining coils of the charger are then energized, so do not consume energy and radiate no magnetic field.

Since the outer contour of the core of the loading device and the recesses of the carrier element of the receiving station each have contours that are adapted to each other and the respective contours are designed rotationally symmetric or polygonal, the charging devices and the receiving stations in any position with respect to the circumferential direction coupled to each other , Thus eliminating advantageously the need to produce a mutually aligned exactly aligned connector; Rather, it is ensured by the outer contour of the charging device, that the receiving station can be placed reliably on this without tilting this when pushed.

Furthermore, the charging device and the receiving station form a common plug-in device, which is sealed watertight, so that the electrical components are protected from penetrating water and can therefore be operated outdoors.

Since the housing covering the coils and the core of the charging device, as well as the housing which closes the coils and the carrier element of the receiving station to the outside, is made of an insulating material, the magnetic field of the coils of the charging device is not in its deflection and its Field strength not hindered or reduced.

Since the charging device has a plurality of steps, which have different outer diameters or height dimensions, it is possible to place these on differently configured receiving stations, which are fastened, for example, firmly to an apparatus to be electrically charged.

Figur 1 a

ein erstes Ausführungsbeispiel einer Ladevorrichtung und einer Empfangsstation mit drei bzw. zwei Stufen, wobei an jeweils zwei Stufen eine Spule angeordnet ist, im entkoppelten Zustand,

Figur 1b

die Ladevorrichtung und die Empfangsstation gemäß Figur 1a im verbundenen Zustand,

Figur 2

die Ladevorrichtung gemäß Figur 1 a und ein zweites Ausführungsbeispiel einer Empfangsstation mit einer Stufe im aufgesteckten Zustand,

Figur 3

ein zweites Ausführungsbeispiel einer Ladevorrichtung mit vier Stufen und drei jeweils einer der Stufen zugeordneten Spule und einem dritten Ausführungsbeispiel einer Empfangsstation mit drei Stufen, an denen jeweils Spulen angebracht sind, im verbundenen Zustand und

Figur 4

eine schematische Darstellung der Ausbildung von Feldlinien, die Magnetfelder bilden, gemäß dem Ausführungsbeispiel nach Figur 1 b.

In the drawing, two embodiments of a charging device according to the invention and three embodiments of a receiving station according to the invention in each case in section, which together form a plug-in device, are shown below. These embodiments and the connector are explained in more detail below. In detail shows:

FIG. 1 a

a first embodiment of a charging device and a receiving station with three or two stages, wherein at each two stages a coil is arranged, in the decoupled state,

FIG. 1b

the loading device and the receiving station according to FIG. 1a in the connected state,

FIG. 2

the charging device according to FIG. 1 a and a second embodiment of a receiving station with a stage in the plugged state,

FIG. 3

A second embodiment of a charging device with four stages and three each associated with one of the stages coil and a third embodiment of a receiving station with three stages, on each of which coils are mounted, in the connected state and

FIG. 4

a schematic representation of the formation of field lines forming magnetic fields according to the embodiment according to FIG. 1 b.

In the FIGS. 1 a and 1 b, a charging device 1 and receiving station 11 are shown, which can be interconnected for inductive energy transfer.

The charging device 1 consists of a core 2, which is made of iron, so a magnetically conductive material. The outer contour 4 of the core 2 is designed stepped or stepped in relation to the longitudinal axis 3 of the core 2. The first stage of the core 2 is provided with the reference numeral 5 and has the largest distance of each further stage 5 '... 5 ⁿ to the longitudinal axis 3. On the outside of the stage 5, a ring segment 33 made of copper for shielding the magnetic field 32 is attached.

Adjacent to the first stage 5, a second stage 5 'is provided, whose outer contour 4 is L-shaped. The second stage 5 'is associated with a wire 6 in the form of a coil formed as a coil 7. The coil 7 is located on both legs the L-shaped stage 5 'and is connected via electrical lines 27 to a power source 10, through which the coil 7 is operated with alternating current in the state of charge, so that it flows through the coil 7. Thus, the coil 7 forms the magnetic field 32, which is explained in detail below.

Adjacent to the second step 5 ', a third step 5 "is provided, the outer contour 4 of which is dimensioned smaller than the distance of the second step 5' relative to the longitudinal axis 3. The third step 5" also has an L-shaped outer contour 4 this is another coil 7 is arranged, which is connected via the electrical line 27 to the power source 10.

By means of a control electronics 35, the coils 7 of the charging device 1 can be separated from each other or coupled to each other, so that a single or more of the coils 7 can be supplied by the power source 10 with electrical energy, thereby generating a smaller or larger magnetic field 32. By the control electronics 35 is namely detectable how many coils 16 of the receiving station 11 are present at all, so that the formation of the magnetic field 32 by the coil 7 to the number of receiving coils 16 is adjustable.

The core 2 and the two coils 7 of the charging device 1 are covered by a housing 31 to the outside, which is made of an insulating material, preferably made of plastic, and thin-walled, so that the magnetic field generated by the coils 32 32 through the housing 31 without Distraction and field strength loss radiates. However, the electrically conductive coils 7 are thereby isolated.

A shoulder 25, which serves as a contact surface, is worked in between the two steps 5 'and 5 ".The shoulder 25 extends inclined at an angle of 45 ° from inside to outside and from top to bottom relative to the longitudinal axis 3 of the core 2.

The receiving station 11 is coupled via the electrical lines 27 with an accumulator 12, is supplied by an unillustrated electric drive motor of a bicycle in the decoupled state between the charging device 1 and the receiving station 11 with electrical energy.

The receiving station 11 consists of a support member 13 which is made of iron, that is, a magnetically conductive material. Two recesses 17 'and 17 "of different size are incorporated into the carrier element 13. The distance between the first recess 17' and the longitudinal axis 14 of the carrier element 13 is greater than the distance between the second recess 17". In essence, the distance between the first and second recesses 17 'and 17 "corresponds to the distance that the second and third stages 5' and 5" of the loading device 1 have with respect to the longitudinal axis 3 of the core 2. The recesses 17 'and 17 "are designed as L-shaped inner wall 18 and the contour of the steps 5' and 5" modeled.

The first stage 5 serves as a shielding attachment 8, through which the forming magnetic field 32 is deflected in a structured manner.

Each of the first and second recesses 17 'and 17 "is associated with a coil 16 made of a wire coil 15. The coils 16 are connected to the accumulator 12 through the electrical lead 27.

The support member 13 and the coils 16 of the receiving station 11 are insulated by a housing 34 to the outside, which is made of a thin-walled plastic material and thus has an insulating effect. However, the magnetic field 32 penetrates the housing 34 without being deflected.

In the bottom of the support member 13, a through hole 19 is incorporated, whose axis of symmetry is aligned with the longitudinal axis 14 and run through the electrical supply line.

In FIG. 1b the connection state between the charging device 1 and the receiving station 11 is shown. Due to the applied alternating voltage, the two coils 7 of the charging device 1 form the magnetic field 32, which is initially deflected in a structured manner by the first step 5 in the region of the shielding projection 8. In addition, the ring segment 33 shields the magnetic field 32, so that almost no scattering losses occur.

The coil 7 of the first stage 5 'and the coil 16 of the first recess 17' are paired inductively interconnected in pairs and therefore run in a common plane 1. The coil 7 of the second stage 5 "and the coil 16 of the second recess 17" are in a further plane 11 which is parallel and spaced from the plane I runs.

Consequently, two pairs of coils 7 and 16 are inductively connected together, so that by the control of the coil 7, the charging device 1, the inductive energy transfer to the coils 16 of the receiving station 11 is accomplished.

Depending on the number of pairs of coils 7 and 16, a transfer takes place, the amount of energy of which can be determined in a defined manner.

In FIG. 2 Although the charging device 1 structurally identical designed, as in the FIGS. 1a and 1b However, the receiving station 11 is provided with only the recess 17 "in which the coil 16 is arranged, which is positioned in alignment with the coil 7 of the third stage 5" of the charging device 1. The coil 7, which is assigned to the second stage 5 ', has no coil partner, so that only electrical energy is transmitted inductively via the coil 7 of the second stage 5 " FIG. 1b reduced; the shutdown of the unneeded coils 7 by means of the control electronics 35th

Due to the L-shaped and staircase-shaped configuration of each stage 5 ... 5 ⁿ is ensured that, for example, a shielding of the magnetic field 32 is effected by these stages 5, 5 ', if only in the area of the third stage 5 "takes place an inductive energy transfer.

In FIG. 3 on the other hand, the charging device 1 and the receiving station 11 are extended by a further pair of coils 7 and 16. In a fourth stage 5 '"namely, a third coil 7 is arranged and the receiving station 11 also has a third coil 16, which is in the region of a third recess 17"' attached.

The step-shaped configuration of the charging device 1 and the receiving station 11 can be expanded as desired, so that the number of coil pairs required is to be provided depending on the amount of energy to be transmitted.

It is for shielding the self-adjusting magnetic field 32 also required to attach to the outside of the support member 13, the ring segment 33, in the transition region between the support member 13 and the housing 34, ie immediately adjacent to the core 2 of the charging device 1. This causes namely as this particular in FIG. 4 is shown, a further advantageous three-dimensional design of the magnetic field 32, so that this is conducted in the region of the pairs of coils 7 and 16 in order to optimize the inductive energy transfer, ie to increase the efficiency and to avoid scattering losses.

The plug-in device formed by the charging device 1 and the receiving station 11 is identified by the reference numeral 21. Namely, the charging device 1 may be associated with a charging station fixedly attached to a building facade, for example, whereas the receiving station may be mounted on a mobile vehicle such as an electric bicycle or an electric scooter, so that it is not necessarily necessary for the charging device 1 and the receiving station 11 are mounted on a common component. The plug-in device 21 is created by the joining of the receiving station 11 to the loading device 1.

In order to avoid unintentional release of the receiving station 11 of the charging device 1, a latching clip or a latching hook is provided, which is mounted hinged to the receiving station 11 and which is einklippsbar on the core 2 or on the housing 31 of the charging device 1. Consequently, the receiving station 11 is then fixed to the charging device 1.

Claims (14)

Charging device (1) for the inductive transmission of electrical energy and which can be connected to a current source (10) with a core (2) made of a magnetically conductive material, which is rotationally symmetrical about a longitudinal axis (3) or whose outer contour (4) to the longitudinal axis (3) has a constant or linearly increasing distance with respect to a perpendicular to the longitudinal axis (3) aligned plane (22, 23, 24), with a wound on the core (2) and a coil (7) forming wire (6) made of electrically conductive material through which current flows in the state of charge and a magnetic field (32) is formed, and with a housing (31) consisting of an electrically insulating material, through which the core (2) and the coil (7) are covered to the outside,
characterized,
that the core (2) consists of at least two steps (5 ', 5 ", ... 5 ⁿ⁾ is formed, that the outer contour of the first stage (5') has a larger distance to the longitudinal axis (3) of the core (2) as the outer contour of the second stage (5 ") and that the coil (7) of the second stage (5") is associated. Device according to claim 1,
characterized,
that at least one third stage (5 ") is worked on the core (2), that the third and each further stage (5"', ... 5 ⁿ ) is associated with a respective coil (7) electrically separated from each other or are interconnectable and that the housing (31) the first and each further stage (5 ', ... 5 ⁿ ) and the coils (7) sheathed. Device according to claim 2,
characterized,
that the mutually adjacent stages (5 ', ... 5 ⁿ ) are arranged in steps in cross-section. Loading device according to one of the preceding claims,
characterized,
in that each of the steps (5, ... 5 ⁿ ) of the core (2) has an L-shaped outer contour in cross-section and in that each of the coils (7) on the L-shaped outer contour of the respective step (5, ⁿ ) is applied. Loading device according to one of the preceding claims,
characterized,
that at the outer contour of the stage (5) which has the greatest distance from the longitudinal axis (3), a ring segment (33) is attached made of copper and that the magnetic field formed by each coil (7) (32) (by the ring segment 33 ) is deflected such that the magnetic field (32) in a predetermined three-dimensional structured training to the loading device (1). Loading device according to one of the preceding claims,
characterized,
in that the loading device (1) is provided as a coupling element and in that a receiving station (11) which is wholly or partly adapted to the outer contour of the loading device (1) can be placed on the coupling element. Receiving station (11) which is electrically connected to at least one accumulator (12), consisting of a support member (13) whose material is magnetically conductive and in which a recess (17) is incorporated, from a coil (16) forming a wire winding (15) whose material is electrically conductive and suitable for the inductive transmission of electrical energy, and which is arranged on the inner wall (18) of the recess (17) extending parallel to the longitudinal axis (14) of the carrier element (15),
characterized,
in that the inner wall (18) of the recess (17) facing the spool (16) is L-shaped or plane in cross-section and that the receiving station (11) serves as a coupling element. Receiving station according to claim 7,
characterized,
that the inner wall (18) are covered of the recess (17) and the outer side of the carrier element (13) by means of a housing (34) of electrically insulating material. Receiving station according to claim 7 or 8,
characterized,
in that the carrier element (13) has at least two recesses (17 '... 17 ⁿ ) of different sizes, which extend in two mutually parallel planes (22, 23, 24) oriented perpendicular to the longitudinal axis (14) of the carrier element (13) , and that the distance of the inner wall (18) of the recesses (17 '... 17 ⁿ ) relative to the longitudinal axis (14) of the support element (13) is designed enlarged from the inside outwards. Receiving station according to claim 9,
characterized,
that the recesses (17 ... 17 ⁿ⁾ are rotationally symmetrical relative or polygonal to the longitudinal axis (14) of the carrier element (13). Receiving station according to claim 9 or 10,
characterized,
that each recess (17 '... 17 ⁿ⁾ is associated with a coil (16) which are electrically decoupled from each other or connected together. Plug-in device (21) for inductive transmission of electrical energy, characterized
in that a first loading device (1) designed as a coupling element is provided, the outer contour (4) of which is stepped in relation to the longitudinal axis (3) is configured such that at least one of the steps (5 '.., 5 ⁿ ) of the step-shaped loading device (1) is provided with a coil (7), that a receiving station (11) serving as a second coupling element for coupling to the first coupling element (1 ) is present, the support element (13) has at least one recess (17 '... 17 ⁿ ) whose distance from the inside to the outside relative to the longitudinal axis (14) of the carrier element (13) increases in steps such that the inner contour of the receiving station (11) is wholly or partially adapted to the outer contour of the loading device (1) that each recess (17 '... 17 ⁿ ) is associated with a coil (16) and that the coils (16) of the first and the second coupling element ( 1, 11) are interconnected pairwise in the mounted state such that the pairs of coils (7, 16) are associated with a common or separate magnetic field (32) for inductive energy transfer. Plug-in device according to claim 12,
characterized,
in that between two pairs of coils (7, 16) on the core (2) and the support element (13) an oblique abutment surface (25) is machined, the course of which is adapted to one another in such a way that they relate to the longitudinal axis (3) of the Kerns (2) and the support element (13), preferably at an angle of 45 °, an outwardly sloping shoulder forms. Plug-in device according to claim 12 or 13,
characterized,
in that a loading device (1) according to one of Claims 1 to 7 is provided as the first coupling element and a receiving station (11) according to one of Claims 8 to 12 is provided as the second coupling element.

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