Sensor having rotationally offset coil pairs and differently formed receiving coils for locating metal or magnetic objects

The invention claimed is: 1. A sensor for locating metal or magnetic objects, the sensor comprising: a first transmitting coil having a plurality of windings arranged in a first plane and centered about a first line in the first plane; a second transmitting coil having a plurality of windings arranged in a second plane and centered about a third line in the second plane that is at a non-parallel angle relative to the first line in the first plane, the second plane being parallel with the first plane; a receiving coil formed from a series connection of a first receiving subcoil and a second receiving subcoil, the first receiving subcoil being directly connected to the second receiving subcoil, the first receiving subcoil having a plurality of windings arranged in the first plane and centered about the first line in the first plane, the second receiving subcoil having a plurality of windings arranged in the second plane and centered about the third line in the second plane; a current supply device connected to each of the first transmitting coil and the second transmitting coil and configured to supply the first transmitting coil and the second transmitting coil with currents; and an evaluation device directly connected to the first receiving subcoil and directly connected to the second receiving subcoil and configured to evaluate a voltage signal across the series connection of the first receiving subcoil and the second receiving subcoil, wherein the first transmitting coil and the first receiving subcoil are opposite one another with respect to a second line in the first plane, the second line in the first plane perpendicularly intersecting the first line in the first plane at a first center point in the first plane, wherein the second transmitting coil and the second receiving subcoil are opposite one another with respect to a fourth line in the second plane, the fourth line in the second plane perpendicularly intersecting the third line in the second plane at a second center point in the second plane, the first center point in the first plane and the second center point in the second plane being arranged so as to coincide with a central axis that is perpendicular to the first plane and the second plane, and wherein the first receiving subcoil and the second receiving subcoil have different inductances. 2. The sensor as claimed in claim 1 , wherein the first line in the first plane and the third line in the second plane are arranged at an angle of 65° to 70° relative to one another. 3. The sensor as claimed in claim 1 , wherein windings of the first receiving subcoil and the second receiving subcoil delimit different areas. 4. The sensor as claimed in claim 1 , wherein the first receiving subcoil and the second receiving subcoil have different numbers of the windings. 5. The sensor as claimed in claim 1 , wherein an average diameter of the windings of the first receiving subcoil differs from an average diameter of the windings of the second receiving subcoil. 6. The sensor as claimed in claim 1 , wherein the windings of the first receiving subcoil have different spacings from one another in comparison to the windings of the second receiving subcoil. 7. The sensor as claimed in claim 1 , wherein: each winding in the plurality of windings of the first transmitting coil comprises (i) a straight section arranged in parallel to the second line in the first plane and (ii) an arc-shaped section having a respective radial center point on the first line in the first plane; each winding in the plurality of windings of the second transmitting coil comprises (i) a straight section arranged in parallel to the fourth line in the second plane and (ii) an arc-shaped section having a respective radial center point on the third line in the second plane; each winding in the plurality of windings of the first receiving subcoil comprises (i) a straight section arranged in parallel to the second line in the first plane and (ii) an arc-shaped section having a respective radial center point on the first line in the first plane; and each winding in the plurality of windings of the second receiving subcoil comprises (i) a straight section arranged in parallel to the fourth line in the second plane and (ii) an arc-shaped section having a respective radial center point on the third line in the second plane. 8. The sensor as claimed in claim 7 , wherein: the arc-shaped section of an outermost winding in the plurality of windings of the first transmitting coil has its respective radial center point at the first center point in the first plane and on the central axis; the arc-shaped section of an outermost winding in the plurality of windings of the second transmitting coil has its respective radial center point at the second center point in the second plane and on the central axis; the arc-shaped section of an outermost winding in the plurality of windings of the first receiving subcoil has its respective radial center point at the first center point in the first plane and on the central axis; and the arc-shaped section of an outermost winding in the plurality of windings of the second receiving subcoil has its respective radial center point at the second center point in the second plane and on the central axis. 9. A sensor for locating metal or magnetic objects, the sensor comprising: a first transmitting coil having a plurality of windings arranged in a first plane and centered about a first line in the first plane; a second transmitting coil having a plurality of windings arranged in a second plane and centered about a third line in the second plane that is at a non-parallel angle relative to the first line in the first plane, the second plane being parallel with the first plane; a receiving coil formed from a series connection of a first receiving subcoil and a second receiving subcoil, the first receiving subcoil being directly connected to the second receiving subcoil, the first receiving subcoil having a plurality of windings arranged in the first plane and centered about the first line in the first plane, the second receiving subcoil having a plurality of windings arranged in the second plane and centered about the third line in the second plane; a current supply device connected to each of the first transmitting coil and the second transmitting coil and configured to supply the first transmitting coil and the second transmitting coil with currents; and an evaluation device directly connected to the first receiving subcoil and directly connected to the second receiving subcoil and configured to evaluate a voltage signal across the series connection of the first receiving subcoil and the second receiving subcoil, wherein the first transmitting coil and the first receiving subcoil are opposite one another with respect to a second line in the first plane, the second line in the first plane perpendicularly intersecting the first line in the first plane at a first center point in the first plane, wherein the second transmitting coil and the second receiving subcoil are opposite one another with respect to a fourth line in the second plane, the fourth line in the second plane perpendicularly intersecting the third line in the second plane at a second center point in the second plane, the first center point in the first plane and the second center point in the second plane being arranged so as to coincide with a central axis that is perpendicular to the first plane and the second plane, wherein the first receiving subcoil and the second receiving subcoil have different inductances, and wherein at least one of (i) the first receiving subcoil and the second receiving subcoil have different numbers of the windings, (ii) an average diameter of the win