Contact system for establishing an electric connection between a vehicle and a power supply

Abstract

The invention relates to a contact system for establishing an electric connection between a vehicle and a power supply having a first pole and a second pole for charging the vehicle, secondary contact surfaces being mounted such that they surround a second insulating surface, wherein the second insulating surface has at least one minimum width which is greater than the peripheral size of one of the contacted primary contact surfaces in the same direction (X, Y, Z).

Claims

1. A contacting system for establishing a physical electrical connection between a vehicle and a power supply with a first terminal and a second terminal for charging the vehicle, with: a primary transmission element which has a plurality of primary contact surfaces arranged in a structured manner, electrically insulated from each other and each having an outer contour, and with a secondary transmission element which has at least one first secondary contact surface, for physically contacting the first terminal, and at least one second secondary contact surface, for physically contacting the second terminal, wherein the secondary contact surfaces are electrically insulated from each other, and with control means which are designed to determine first primary contact surfaces which are in direct physical and electrical contact with the first secondary contact surface and which are designed to determine second primary contact surfaces which are in direct physical and electrical contact with the second secondary contact surface, and which are designed to establish an electrical connection via the first primary contact surfaces and the first secondary contact surface, between the first terminal of the power supply and the first terminal of the vehicle, and which are designed to establish an electrical connection via the second primary contact surfaces and the second secondary contact surface for supplying energy to the vehicle, characterized in that a second insulating surface surrounding the secondary contact surfaces is provided, which has at least one optionally direction-dependent minimum width which is greater than an extent of the contour of one of the contacted primary contact surfaces in a same direction (X, Y, Z).

2. The contacting system according to claim 1, characterized in that the second insulating surface has at least one minimum width which is greater than a diameter of a circumference around a largest outer contour of one of the contacted primary contact surfaces.

3. The contacting system according to claim 1, characterized in that the second secondary contact surface completely surrounds the first secondary contact surface and in that the second insulating surface completely surrounds the second secondary contact surface.

4. The contacting system according to claim 3, characterized in that the first secondary contact surface is arranged in a center of the second secondary contact surface and in that the second secondary contact surface and the second insulating surface form concentric circles around the first secondary contact surface.

5. The contacting system according to claim 4, characterized in that a first insulating surface is arranged as a concentric circle around the first secondary contact surface between the first secondary contact surface and the second secondary contact surface, wherein the first insulating surface likewise has at least one, direction-dependent minimum width which is greater than the extent of the contour of one of the contacted primary contact surfaces in the same direction.

6. The contacting system according to claim 1, characterized in that the primary contact surfaces are formed as hexagons.

7. The contacting system according to claim 1, characterized in that the primary contact surfaces are arranged in a shape of a grid.

8. The contacting system according to claim 1, characterized in that there is a voltage of over 60 volts between the first terminal and the second terminal.

9. The contacting system according to claim 1, characterized in that the control means are formed to switch all primary contact surfaces potential-free which have been determined neither as first primary contact surface nor as second primary contact surface by the control means.

10. The contacting system according to claim 1, characterized in that the primary transmission element is provided in a road surface of a parking space and the secondary transmission element is provided in the vehicle such that it can be lowered and lifted for contacting the primary transmission element.

11. The contacting system according to claim 1, characterized in that positioning means are provided for direction-dependent positioning of the secondary transmission element on the primary transmission element and in that the minimum width of the second insulating surface varies depending on the direction.

12. The contacting system according to claim 11, characterized in that the outer contour of the primary contact surfaces is direction-dependent and in that, if secondary contact surfaces are positioned by the positioning means on the primary contact surfaces, the minimum width of the second insulating surface corresponds in a direction-dependent manner at least to the width of the primary contact surface in the same direction (X, Y, Z).

13. The contacting system according to claim 12, characterized in that the outer contour of the primary contact surfaces is oval shaped.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 shows a first embodiment of the contacting system according to the invention, in which a second secondary contact surface completely surrounds a first secondary contact surface of the secondary transmission element.

(2) FIG. 2A shows a primary contact surface of the primary transmission element according to FIG. 1 in an enlarged representation.

(3) FIG. 2B shows the secondary contact surfaces of the secondary transmission element according to FIG. 1.

(4) FIG. 3 shows the primary contact surfaces of the primary transmission element arranged in the shape of a grid according to FIG. 1.

(5) FIG. 4 shows a second embodiment of the contacting system according to the invention, in which a first secondary contact surface and a second secondary contact surface are designed as a segment of a circle and are surrounded by an insulating surface.

(6) FIG. 5 shows the primary transmission element and the secondary transmission element of a third embodiment of the contacting system according to the invention, in which the outer contour of the primary contact surfaces and the width of the second insulating surface of the secondary transmission element differ in width in a direction-dependent manner.

(7) FIG. 6 shows a primary contact surface of the primary transmission element according to FIG. 5 in an enlarged representation.

DETAILED DESCRIPTION OF THE INVENTION

(8) FIGS. 1 to 3 show a first embodiment of a contacting system 1 for establishing an electrical connection between a vehicle and a power supply with a positive terminal and a negative terminal for charging the vehicle. Of the vehicle, only a battery 2, a charging circuitry 3 and a secondary transmission element 4 are shown, through which power is supplied to the vehicle for charging the battery 2. In FIG. 2B, a first secondary contact surface 5, which is connected via the charging circuitry 3 to the positive terminal of the battery 2, and a second secondary contact surface 6, which is connected via the charging circuitry 3 to the negative terminal of the battery 2, of the secondary transmission element 4 are shown.

(9) The contacting system 1 furthermore has a primary transmission element 7 embedded in or fitted on the road surface of a parking space, shown in FIG. 3, which has a plurality of primary contact surfaces 8 with a uniform hexagonal outer contour arranged in a structured manner, and in particular in the shape of a grid, electrically insulated from each other. A circumference with a diameter D determines the outer contour of the primary contact surfaces 8.

(10) The contacting system 1 furthermore has control means 9 which are connected to each of the primary contact surfaces 8. For the sake of better clarity, only a few of these connecting lines 10 are represented in FIG. 1. The control means 9 are furthermore connected to a voltage source 11, which is hooked up to the local power grid with, for example, 380 volts and makes a direct voltage of 60 volts, 120 volts, 200 volts or more available between the positive terminal and the negative terminal. The control means 9 are designed to determine first primary contact surfaces 12 which are in contact with the first secondary contact surface 5 and are designed to determine second primary contact surfaces 13 which are in contact with the second secondary contact surface 6. After determining the first primary contact surfaces 12 and the second primary contact surfaces 13, the control means 9 are designed to establish an electrical connection between the positive terminal of the voltage source 11 and the first primary contact surfaces 12 and to establish an electrical connection between the negative terminal of the voltage source 11 and the second primary contact surfaces 13. An electrical connection is thus hereby established between the positive terminals and the negative terminals of the voltage source 11 and of the charging circuitry 3 in the vehicle, whereupon the charging circuitry transforms the voltage of 60 volts or more supplied to it into the voltage of, for example, 400 volts required in the vehicle.

(11) The secondary transmission element 4 of the contacting system 1 now has a second insulating surface 14 with a width B surrounding the secondary contact surface 6, which has at least one minimum width which corresponds to the diameter D of the circumference around the outer contour of one of the primary contact surfaces 8. It is hereby ensured that none of the second primary contact surfaces 13 connected to the negative terminal can be contacted with a person's finger. To further increase the safety, the second insulating surface 14 may have a width B exceeding the minimum width in order that second primary contact surfaces 13 can also no longer be contacted with, for example, a metallic rod pushed between the primary transmission element 7 and the secondary transmission element 4. The safety is, however, guaranteed in any case as long as the second insulating surface 14 has at least the minimum width. The advantage is hereby obtained that the required safety is guaranteed in spite of the high direct voltage of 60 volts or more with correspondingly high charging currents and thus short charging cycles of the vehicle's battery 2.

(12) One of the primary contact surfaces 8 is shown enlarged in FIG. 2A. The outer contour of the primary contact surface 8 has an extent in a direction X which specifies a direction-dependent minimum width W1 of the second insulating surface. The outer contour of the primary contact surface 8 has an extent in a direction Y which specifies the direction-dependent minimum width W2 of the second insulating surface, which corresponds to the diameter D. According to the first example, the second insulating surface 14 has a width B, wherein B>W1 and B>W2. The advantage is hereby obtained that the secondary transmission element 4 can be lowered in any desired alignment onto the primary transmission element 7 for contacting.

(13) In the contacting system 1 according to the first embodiment of the invention, the second secondary contact surface 6 completely surrounds the first secondary contact surface 5, which is why the first secondary contact surface 5 is also completely surrounded by the second insulating surface 14. It is hereby advantageously also ensured by the second insulating surface 14 that the first secondary contact surface 5 also cannot be contacted with a user's finger.

(14) A particularly advantageous embodiment is provided when the first secondary contact surface 5 is arranged in the centre of the second secondary contact surface 6 and when the second secondary contact surface 6 and the second insulating surface 14 form concentric circles around the first secondary contact surface 5. The first secondary contact surface 5 is particularly well shielded hereby.

(15) It is furthermore particularly advantageous to arrange a first insulating surface 15 as a concentric circle around the first secondary contact surface 5 between the first secondary contact surface 5 and the second secondary contact surface 6, wherein the first insulating surface 15 with the width B likewise has at least the minimum width W2. The electrical insulation of the first secondary contact surface 5 from the second secondary contact surface 6 that is necessary for voltages of 60 volts or more is hereby guaranteed and it is furthermore achieved that the first secondary contact surface 5 is protected particularly well from unwanted touching by people.

(16) It has furthermore proved to be advantageous to form the primary contact surfaces 8 as hexagons. Compared with circular primary contact surfaces known from the state of the art, this makes it possible to form particularly large primary contact surfaces 8 with a large surface area in order to transmit strong charging currents without destroying the contact surfaces 8. Other shapes of primary contact surfaces, such as for example rectangular, octagonal, oval or triangular, would likewise be possible.

(17) The control means 9 are advantageously formed to switch all primary contact surfaces 8 potential-free which have been determined neither as first primary contact surface 12 nor as second primary contact surface 13. It is hereby ensured that all primary contact surfaces 12 and 13 of the primary transmission element 7 that are not necessary for transmitting power in order to charge the vehicle can be touched by a person without electrifications or short circuits of the contacting system 1 possibly resulting.

(18) FIG. 4 shows a second embodiment of a contacting system 16 according to the invention, wherein only the contact surfaces of a secondary transmission element 17 are formed differently. The secondary transmission element 17 has a first secondary contact surface 18 and a second secondary contact surface 19, which are both designed as a segment of a circle. Both secondary contact surfaces 18 and 19 are surrounded by an insulating surface 20 which forms a first and a second insulating surface. Advantageously, the insulating surface 20 also has a width B between the secondary contact surfaces 18 and 19, corresponding to a first insulating surface, and around the secondary contact surfaces 18 and 19, corresponding to a second insulating surface, which width is greater than the minimum width W2 and the diameter D of the circumference around the outer contour of the primary contact surface 8. In the contacting system 16 according to the second embodiment, the required safety is thus also provided in order to achieve short charging cycles with high direct voltages in the case of direction-independent contacting of the primary transmission element 7 with the secondary transmission element 17.

(19) FIG. 5 shows a primary transmission element 21 according to a third embodiment of a contacting system 22 according to the invention, in which the outer contour of primary contact surfaces 23 is oval and thus direction-dependent. A secondary transmission element 24 has a first secondary contact surface 25 and a second secondary contact surface 26, which are electrically insulated from the outside by a second insulating surface 27 and from each other by a first insulating surface 28. According to the invention, the second insulating surface 27 must, in a direction-dependent manner, have only the minimum width, which is greater than the extent of the contour of the contacted primary contact surface 23 in the same direction.

(20) FIG. 6 shows the primary contact surface 23 of the contacting system 22 in an enlarged representation. In direction X the contour of the primary contact surface 23 has an extent which corresponds to a minimum width W3 in direction X. In direction Y the contour of the primary contact surface 23 has an extent which corresponds to a minimum width W4 in direction Y. In order to form the secondary transmission element 24 particularly narrow, the second insulating surface 27 has a width B1 when primary and secondary contact surfaces are in contact with each other. As the extent of the primary contact surface 23 in direction Y is larger: B2>W4 and B1>W3 applies. In a direction Z inclined by, for example, 45 degrees with respect to the direction X and to the direction Y, the second insulating surface 27 has a width which is greater than the extent of the primary contact surface 23 in the same direction Z. The advantage is hereby obtained that the secondary transmission element 24 can be formed particularly narrow in order to be able to integrate it well into a vehicle.

(21) The contacting system 22 according to the third embodiment of the invention now has positioning means in order to ensure that the secondary transmission element 24 is positioned on the primary transmission element 21 in a direction-dependent manner, i.e. substantially corresponding to the directions X and Y represented in FIGS. 5 and 6. Positioning means may be formed by a sensor, a camera with image recognition or by mechanical means, wherein further possibilities are known to a person skilled in the art. A rough alignment is already provided by the parking space arrangement, which is why positioning means may also be provided by lateral elevations in the road surface to the left and right of the parking space, which ensure that the vehicle can only be parked in this direction.

(22) It can be mentioned that direct voltages of 80, 100 or 400 volts, as well as alternating voltages in similar voltage ranges may also be applied to the contact surfaces of the transmission elements with the second insulating surface. It is also possible to form contact surfaces for more than two terminals with the second insulating surface, with the result that for example three-phase alternating current can be transmitted. Further alternating voltages with different voltage amplitude or frequency could be transmitted via further secondary contact surfaces. Likewise, the transmission of data with respect to, for example, the charge state of the vehicle would be possible via further secondary contact surfaces. The primary transmission means could also be provided on the vehicle, and the secondary transmission means could be provided in the road surface of a parking space. The insulating surface can be formed by a material known to a person skilled in the art, such as plastic or ceramic.