JP2005529028A - Primary conductor configuration for systems for inductive transmission of electrical energy - Google Patents

Abstract

Providing a primary conductor configuration (1) for a system for inductive transmission of power. The conductor configuration (1) comprises an output line (2) and a return line 3, wherein the output line (2) and the return line (3) are arranged at a position parallel to at least some parts, and the output line (2) and the return line 3 It can be connected to a current source (4) so that a current flows through the line (3). The primary conductor configuration (1) of the present invention provides as wide a range as possible for the consuming part that can be displaced along the primary conductor configuration (1), and the conductor configuration (1) is divided into a plurality of adjacent portions (A, (B, C, D, E, F, G, H) makes it possible to give a magnetic field strength distribution that is as uniform as possible along the entire configuration. Each part (A, B, C, D, E, F, G, H) is connected to the output line (2) and the return line (3) and the connection line (3) connecting the output line (2) and the return line (3). 5). Each portion (A, B, C, D, E, F, G, H) is arranged such that two consecutive portions overlap in a region (7) close to the connection line (5).

Description

  The present invention relates to a primary conductor configuration for a system for inductive transmission of electrical energy according to the preamble of claim 1.

  A conductor configuration for contactless induction transfer of energy, in which the primary circuit is formed by two parallel lines separated from each other by a certain distance, is known from the prior art, for example from DE 197 46 919 A1. Generally known by. A mobile consumer, including a secondary circuit, such as a ground transportation vehicle, can be displaced along such a primary conductor configuration, and the secondary circuit described above is capable of transferring electrical energy from the magnetic field generated by the current carrying primary circuit. Useful for inductive acceptance.

  A known primary conductor configuration is formed by a conductor loop that is installed along a line segment and connected to a current source. The conductor loop thus comprises a conductor line and a return line, the conductor line and the return line being placed so that they extend parallel to each other and are separated by a certain distance. The current source supplies current to the primary circuit thus formed, and the current flows in the opposite direction through the output line and the return line.

  The sufficient energy density of the magnetic field generated by the primary circuit is only along the conductor configuration with a conventional current source if the conductor configuration has a limited range, i.e. limited length output and return lines. Can be achieved.

  However, there is a problem that a conductor configuration of essentially any length is required to provide an appropriate range for the vehicle, particularly in the induction energy supply of ground transportation vehicles. It is also desirable to achieve a substantially uniform field strength distribution along the primary circuit, i.e., a substantially uniform density of the magnetic field generated by the primary circuit.

  The object of the present invention is therefore to develop a primary conductor configuration for inductive transmission of electrical energy to a movable consumer that allows as wide a range as possible for the consumer that can be displaced along the primary conductor configuration. And a substantially uniform field strength distribution is generated along the primary conductor configuration when current is applied.

  In the primary conductor configuration according to the preamble of claim 1, this object is achieved by the features disclosed in the characterizing portion of claim 1. Advantageous embodiments of the invention are disclosed in the dependent claims.

  The present invention proposes to divide the conductor configuration into a plurality of adjacent parts, each part comprising an output line and a return line and a connecting line connecting the output line and the return line, each part having 2 Two consecutive parts are arranged relative to each other so that they overlap in a region close to their connecting lines. Dividing the primary circuit into several parts makes it possible to achieve a sufficiently high magnetic field density along the entire conductor configuration, since the current can be applied separately to each part by the current source. Their overlap at the edges of adjacent parts ensures a uniform field strength distribution in this transition region. The largely uniform transition of the magnetic field strength distribution from one part to the adjacent part not only ensures a uniform energy supply to the movable consumer along the primary circuit line segment, but also the primary circuit magnetic field line. This is especially necessary when used simultaneously to track mobile consumers along the minute.

  The present invention will be described in more detail below with reference to embodiments shown in the accompanying drawings.

  FIG. 1 schematically shows a primary circuit for a system for inductive transfer of electrical energy formed by a primary conductor configuration 1 according to the invention, which system can be displaced along the primary conductor configuration 1 Used to transmit electrical energy to the consumer. The primary conductor configuration 1 is divided into a plurality of adjacent portions (A to H). Each of these portions (A to H) includes an output line 2, a return line 3, and a connection line 5 that connects the output line and the return line. The output lines and return lines of the parts (A to H) are identified by reference numerals 2X, 3X and 5X in FIG. 1, respectively, where X denotes the respective conductor part (A to H).

  The output line 2 and the return line 3 are arranged parallel to each other in each part A to H, and the connection line 5 forms a transition between the output line 2 and the return line 3. In this context, the term parallel configuration of the output line and the return line refers to the output line and the return line 3 being separated from each other by a certain distance. Each line extends in a straight line as shown in portions A, C, E and G, or is bent to form a curve as shown in portions B, D, F and H. The cable forming the primary conductor configuration 1 is realized in the form of a collective conductor. Each part (AH) of the primary conductor configuration 1 includes a current source 4 for applying a current to the conductor loop of the respective part formed by the output line 2, the connecting line 5 and the return line 3. In the portion identified by reference symbol A in FIG. 1, the output line 2A is connected to the current source 4A via supply lines 8A and 9A. The supply lines 8A and 9A extend substantially at right angles to the output line 2A.

  The other parts BH have one respective current source 4B, 4C,. . . 4H is similarly provided, and the current source is connected to either the output line 2 or the return line 3.

  One respective adjacent portion is located on each side of each portion of the primary conductor configuration to form an extension of output line 2 and return line 3, respectively, as shown in FIG. For example, the part B is located on the right side of the part A, and the part H is located on the left side of the part A. Adjacent portions are arranged relative to each other such that they overlap in an overlapping region 7 near the respective connection line 5. This overlap is realized such that one part of the output line 2X extends directly upward and is closely adjacent to the corresponding output line 2X + 1 of the adjacent part in the overlapping region 7. This applies analogously to the return line 3 of the adjacent part in the overlapping region 7.

  FIG. 2 shows a detailed view of the overlapping region 7 between the two parts A and B. FIG. FIG. 2 shows that the length of the overlapping region 7 in the longitudinal direction of the output line and the return line substantially corresponds to the length of the respective connection lines 5A and 5B curved in a semicircular shape. This is why the primary conductor configuration has a circular winding shape when viewed from above. However, the overlapping region 7 is larger and can be, for example, about twice the length of the connecting line.

  FIG. 3 also shows an overlapping region 7 between two adjacent portions A and B, provided near the region 7 where current supply points for applying current to the output lines 2A and 2B of the respective portions A and B overlap. It is done. These current supply points are formed by supply lines 8B, 9B and 8A, 9A that branch from the respective output lines 2B and 2A and are connected to the current source 4. Each supply line 8B, 9B and 8A, 9A extends substantially perpendicular to each output line 2B and 2A. The supply lines 8, 9 are installed in the plastic tube 10 in close proximity to one another. As an alternative to the plastic tube 10, the supply lines 8 and 9 can also be installed in close proximity to one another by cable ties. Due to the right-angle alignment of the supply lines 8, 9 with respect to the output line 2, an undesirable magnetic interference field is not generated by the supply line in the longitudinal direction of the output line or the return line. The slopes or curved portions forming the transitions from the supply lines 8, 9 to the corresponding output lines 2 and return lines 3, respectively, are made as short as possible and curve with the smallest possible radius without kinking. In another embodiment not shown in the figure, the two supply lines 8, 9 are placed so that they are on top of each other in a curved region. A largely uniform field distribution of the magnetic field generated by the current conducting conductor configuration is thus achieved in the vicinity of the current supply point.

  FIG. 4 shows an embodiment in which the current supply point of part B is arranged near the overlapping region 7. In contrast, the feed point of the adjacent part A is separated from the overlapping region 7 by a greater distance and is therefore not visible in the details described in FIG.

FIG. 5 shows the intersection of two primary conductor configurations 1a and 1b. According to this figure, the output and return lines of the two parts B _1b and B _1a of the two primary conductor configurations 1a and 1b intersect at the intersection region 11. The region 7 that overlaps each adjacent portion A _1b and A _{1a of the} corresponding primary conductor configuration 1a and 1b is preferably at a sufficient distance from the intersection region 11. In this context, the term sufficient distance refers to at least the electrical effective length of the secondary winding of the energy accepting unit of the movable consumer.

  In order to be able to adjust the primary conductor configuration and the energy accepting unit of the movable consumer carrying the secondary winding to resonate, at least one adjustable capacitor 12 is provided for each part (A˜ H). FIG. 6 shows a detailed view of one part in the primary conductor configuration. One respective adjustable capacitor 12 is inserted in the output line 2 as well as in the return line 3 via the branch lines 13, 14; 15, 16. The branch lines 13, 14 of the output line 2 are arranged with a certain distance along the primary conductor configuration with respect to the branch lines 15, 16 of the return line 3, and the distance is at least the energy of the movable consumer It is the same size or larger than the electrical effective length of the receiving unit.

It is the schematic of a primary conductor structure. FIG. 2 is a detailed perspective view of an overlapping region between two portions of the primary conductor configuration shown in FIG. 1. FIG. 2 is a detailed perspective view of an overlapping region between two portions of the primary conductor configuration shown in FIG. 1 near an overlapping region of two current supply points. FIG. 2 is a detailed perspective view of an overlapping region between two portions of the primary conductor configuration shown in FIG. 1 near an overlapping region of one current supply point. It is a perspective view of the cross | intersection part between the primary conductor structures described in FIG. FIG. 2 is a detailed perspective view of the output and return lines of a portion of the primary conductor configuration shown in FIG. 1 with a conditioning capacitor inserted in the output and return lines, respectively.

Claims (10)

A primary conductor configuration (1) for a system for inductive transmission of electrical energy, comprising:
The primary conductor configuration extends parallel to each other and can be connected to a current source (4) to apply current to the output line (2) and the return line (3). ), And the primary conductor configuration (1) is divided into a plurality of adjacent portions (A, B, C, D, E, F, G, H), each portion being the output line (2) and the Including a return line (3) and a connection line (5) connecting the output line and the return line, so that two adjacent portions overlap in a region (7) near the connection line (5). Primary conductor configuration (1) characterized in that the parts are arranged relative to each other. The primary conductor configuration of claim 1,
The primary conductor configuration characterized in that the length L of the overlapping region (7) substantially corresponds to the length of the connecting line (5). The primary conductor configuration according to claim 1 or 2,
The primary conductor configuration, wherein the continuous portions overlap in the longitudinal direction of the primary conductor configuration (1). The primary conductor configuration according to any one of claims 1 to 3,
The primary conductor configuration, wherein the output line (2) and the return line (3) of one part are on the output line and the return line of the adjacent part of the overlapping region (7). The primary conductor configuration according to any one of claims 1 to 4,
The free end (6) of the output line or return line of each part is connected to a pair of supply lines (8, 9) for connecting the output line or return line to a current source (4), Primary conductor arrangement characterized in that supply lines (8, 9) extend substantially perpendicular to the output line (2) or the return line (3). The primary conductor configuration according to claim 5,
The two supply lines (8, 9) of one part forming a pair each include a linear region and an adjacent curved region, the linear regions extending in parallel and closely adjacent to each other, Primary conductor arrangement characterized in that the curved regions of the supply lines cross over each other. 7. Inductive transmission of electrical energy with a primary conductor configuration according to any one of claims 1 to 6 for transmission of electrical energy to a consumption part that can be displaced along the primary conductor configuration (1). A system for
The system wherein the consumption part comprises an energy receiving unit for inductive reception of electrical energy from the magnetic field generated by the primary conductor configuration (1). The system of claim 7, comprising:
A system characterized in that each part (A, B, C, D, E, F, G, H) of the primary conductor configuration (1) is supplied with current by a separate current source (4). The system according to claim 7 or 8, comprising:
5. A crossing region (11) comprising two intersecting primary conductor configurations (1a, 1b) according to any one of claims 1 to 4, wherein the overlapping region (7) of said portions of each conductor configuration (1a, 1b). ) Outside the system. A system according to any one of claims 7 to 9, wherein
Resonance adjustment is realized by inserting at least one adjustable capacitor (11, 12) into the output line (2) and the return line (3) of each part of the conductor configuration, and the adjustable capacitor is connected to the branch line. (13, 14, 15, 16) connected to the output line or the return line, and the branch line (13, 14) of the output line and the branch line (15, 16) of the return line are at least the A system characterized in that they are arranged offset relative to each other by a distance A equal to or greater than the electrical effective length of the energy receiving unit of the consumption part in the longitudinal direction relative to the primary conductor configuration.

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