Electric machine and use thereof

Abstract

An electric machine is selectively operated as a transformer for AC voltage operation or as a throttle system for DC voltage operation. A transformer core has two limbs. An additional winding with a first additional partial winding is wound around a first limb and a second additional winding is wound around the second limb. A higher-voltage winding with a first higher-voltage partial winding is wound around the first additional partial winding and a second higher-voltage partial winding is wound around the second additional partial winding. A first traction winding is wound around the first higher-voltage partial winding and a second traction winding is wound around the second higher-voltage partial winding. A first DC voltage winding may be wound around the first traction winding and a second DC voltage winding may be wound around the second traction winding.

Claims

1. An electric machine for selective operation as a transformer for AC voltage operation or as a throttle system for DC voltage operation, the electric machine comprising: a transformer core with two limbs including a first limb and a second limb; an additional winding with a first additional partial winding wound around said first limb and a second additional partial winding electrically connected to said first additional partial winding and wound around said second limb of said transformer core; a higher-voltage winding with a first higher-voltage partial winding wound around said first additional partial winding and a second higher-voltage partial winding electrically connected to said first higher-voltage partial winding and wound around said second additional partial winding; a first traction winding wound around said first higher-voltage partial winding, and a second traction winding wound around said second higher-voltage partial winding.

2. The electric machine according to claim 1, further comprising a first DC voltage winding wound around said first traction winding and a second DC voltage winding wound around said second traction winding.

3. The electric machine according to claim 1, wherein said transformer core is formed of a ferromagnetic material or a ferrimagnetic material.

4. The electric machine according to claim 1, wherein said first additional partial winding and said second additional partial winding are electrically connected in series.

5. The electric machine according to claim 1, wherein said first higher-voltage partial winding and said second higher-voltage partial winding are electrically connected in parallel.

6. The electric machine according to claim 1, wherein: said first additional partial winding is one of at least two first additional partial windings arranged one behind another along said first limb and wound around said first limb in each instance; each of said first additional partial windings having a first higher-voltage partial winding wound around said first additional partial winding and each said first higher-voltage partial winding having a first traction winding wound around said first higher-voltage partial winding.

7. The electric machine according to claim 1, wherein: said second additional partial winding is one of at least two second additional partial windings arranged one behind another along said second limb and wound around said second limb in each instance; each of said second additional partial windings having a second higher-voltage partial winding wound around said second additional partial winding and each said second higher-voltage partial winding having a second traction winding wound around said second higher-voltage partial winding.

8. In combination with a vehicle having a vehicle drive to be selectively supplied with electrical energy from an external AC voltage or DC voltage, the electric machine according to claim 1, wherein: during AC voltage operation, the external AC voltage is applied to the higher-voltage winding, the additional winding is grounded on one side and otherwise remains electrically unconnected and the traction windings are connected in each instance to a current converter for the vehicle drive; and during DC voltage operation, the higher-voltage winding is grounded on one side and otherwise remains electrically unconnected, the additional winding is short-circuited and grounded on one side and the traction windings are connected in each instance as a network filter throttle for a DC voltage drive train of the vehicle drive.

9. The combination according to claim 8, wherein the electric machine has a first DC voltage winding wound around the first traction winding and a second DC voltage winding wound around the second traction winding, wherein the DC voltage windings are grounded on one side during AC voltage operation and otherwise remain electrically unconnected and wherein at least one DC voltage winding is electrically connected in series with a traction winding during DC voltage operation.

10. The combination according to claim 8, wherein the vehicle drive is supplied with electrical energy via a catenary line system during AC voltage operation by way of an external AC voltage and during DC voltage operation with an external DC voltage.

Description

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING

(1) FIG. 1 shows a schematic sectional representation of an electric machine;

(2) FIG. 2 shows a schematic representation of a connection of the windings of an electric machine during AC voltage operation; and

(3) FIG. 3 shows a schematic representation of a connection of the windings of an electric machine during DC voltage operation.

(4) Mutually corresponding and equivalent parts and elements are provided with the same reference numerals throughout the figures.

DETAILED DESCRIPTION OF THE INVENTION

(5) Referring now to the figures of the drawing in detail and first, particularly, to FIG. 1 thereof, there is shown a schematic sectional representation of an electric machine 1. The electric machine 1 includes a transformer core 3 with two limbs 5, 6 which are parallel to one another, and which are connected to one another by two yokes 7, 8 which are parallel to one another. A number of windings 20, 30, 40, 50, 60, 70 which are described in more detail below are wound around each limb 5, 6. FIG. 1 only shows regions between the limbs 5, 6, in which the windings 20, 30, 40, 50, 60, 70 each proceed, but not individual conductors or turns of the windings 20, 30, 40, 50, 60, 70. Furthermore, the regions of the windings 20, 30, 40, 50, 60, 70 which correspond thereto are not shown, which in the plane of the drawing connect to the two outer sides of the limbs 5, 6, i.e. are found to the left and to the right of the transformer core 3.

(6) The limbs 5, 6 and the yokes 7, 8 of the transformer core 3 are preferably manufactured from a ferromagnetic or ferrimagnetic material.

(7) The windings 20, 30, 40, 50, 60, 70 comprise: an additional winding 20, a higher-voltage winding 30, two traction windings 40, 50 and two DC voltage windings 60, 70.

(8) The additional winding 20 includes a first additional partial winding 21 wound around a first limb 5 of the transformer core 3 and a second additional partial winding 22 preferably electrically connected in series with the first additional partial winding 5 and wound around the second limb 6 of the transformer core 3.

(9) The higher-voltage winding 30 includes a first higher-voltage partial winding 31 wound around the first additional partial winding 21 and a second higher-voltage partial winding 32 electrically connected in parallel with the first higher-voltage partial winding 31 and wound around the second higher-voltage partial winding 32.

(10) A first traction winding 40 is wound around the first higher-voltage partial winding 31. The second traction winding 50 is wound around the second higher-voltage partial winding 32.

(11) A first DC voltage winding 60 is wound around the first traction winding 40. The second DC voltage winding 70 is wound around the second traction winding 50.

(12) Here the first additional partial winding 21, the first higher-voltage partial winding 31, the first traction winding 40 and the first DC voltage winding 60 are wound concentrically around the first limb 5.

(13) The second additional partial winding 22, the second higher-voltage partial winding 32, the second traction winding 50 and the second DC voltage winding 70 are wound concentrically around the second limb 6.

(14) FIGS. 2 and 3 each show a schematic representation of a connection of the windings 20, 30, 40, 50, 60, 70 of the electric machine 1 shown in FIG. 1. FIG. 2 thereby illustrates AC voltage operation and FIG. 3 illustrates DC voltage operation. Here the electric machine 1 is used in a vehicle which has a vehicle drive 80, which is optionally supplied with electrical energy by means of an external AC voltage or an external DC voltage via in each instance a catenary line system 90. The catenary line system 90 includes for instance a catenary line 91, which is embodied for instance as an overhead line, and a grounded return line 92, which is realized for instance as a railway track. The AC voltage or DC voltage is present between the catenary line 91 and the return line 92 in each instance.

(15) FIG. 2 shows the connection of the windings 20, 30, 40, 50, 60, 70 during AC voltage operation of the electric machine 1.

(16) Here a first end of the higher-voltage winding 30 is electrically connected to the catenary line 91 by way of a first higher-voltage winding terminal 33 and a second end of the higher-voltage winding 30 is connected to the return line 92 via a second higher-voltage winding terminal 34.

(17) The first traction winding 40 is connected at a first end via a first traction winding terminal 41 and at a second end via a second traction winding terminal 42 to a current converter (not shown in more detail) for the vehicle drive 80. The second traction winding 50 is connected at a first end via a third traction winding terminal 51 and at a second end via a fourth traction winding terminal 52 to a current converter (not shown in more detail) for the vehicle drive 80.

(18) The first DC voltage winding 60 is only electrically connected to the return line 92 via a second DC voltage winding terminal and is as a result grounded on one side, and otherwise remains electrically unconnected. The second DC voltage winding 70 is only electrically connected to the return line 92 via a second DC voltage winding terminal 72 and is as a result grounded on one side, and otherwise remains electrically unconnected. The additional winding 20 is only electrically connected to the return line 92 via a second additional winding terminal 24 and is as a result grounded on one side, and otherwise remains electrically unconnected.

(19) FIG. 3 shows the connection of the windings 20, 30, 40, 50, 60, 70 during DC voltage operation of the electric machine 1.

(20) The higher-voltage winding 30 is only electrically connected to the return line 92 via the second higher-voltage winding terminal 34 and is as a result grounded on one side and otherwise remains electrically unconnected.

(21) The additional winding 20 is short-circuited by an electrical connection between the two additional winding terminals 23, 24, and is connected to the return line 92 via the second additional winding terminal 24 and is as a result grounded.

(22) The first traction winding 40 is electrically connected to the catenary line 91 via the first traction winding terminal 41, and to the first DC voltage winding 60 via the second traction winding terminal 42 and the first DC voltage winding terminal 61. The first DC voltage winding 60 is also electrically connected to a DC voltage drive train (not shown in more detail) of the vehicle drive 80 via the second DC voltage winding terminal 62. As a result, the first traction winding 40, the first DC voltage winding 60 and its terminals 41, 42, 61, 62 operate as a network filter throttle for the DC voltage drive train of the vehicle drive 80.

(23) The second traction winding 50 is electrically connected to the catenary line 91 by way of the third traction winding terminal 51, and to the second DC voltage winding 70 by way of the fourth traction winding terminal 52 and the third DC voltage winding terminal 71. The second DC voltage winding 70 is also electrically connected to a DC voltage drive train (not shown in more detail) of the vehicle drive 80 via the fourth DC voltage winding terminal 72. As a result, the second traction winding 50, the second DC voltage winding 70 and its terminals 51, 52, 71, 72 similarly operate as a network filter throttle for the DC voltage drive train of the vehicle drive 80.

(24) Alternatively to the exemplary embodiment shown in FIGS. 1 to 3, the DC voltage windings 60, 70 can be omitted in other exemplary embodiments for instance, if due to the traction windings 40, 50 alone, network filter throttles with sufficient inductances can already be realized for the DC voltage operation and/or a traction winding 40, 50 can only be wound around the respective higher-voltage partial winding 31, 32 on each limb 5, 6.

(25) The vehicle is for instance a rail car or an electric locomotive of a train, generally referred to as a multi-system electric locomotive (i.e., one that can operate in more than one railway electrification system). To operate such a vehicle in the different voltage systems (e.g., in the above-mentioned European traction power system, or in the Metro North rail system), the electric machine 1 is configured to convert AC voltages with 15 kV or 25 kV into AC voltages required by the vehicle drive 80 during AC voltage operation, and during DC voltage operation to realize network filter throttles with the required inductances for DC voltages with 3 kV and/or 1.5 kV by means of the traction windings 40, 50 and (optionally) the DC voltage windings 60, 70.

(26) Although the invention has been illustrated and described in greater detail on the basis of preferred exemplary embodiments, the invention is not limited by the disclosed examples and other variations can be derived herefrom by the person skilled in the art without leaving the scope of protection of the invention.