Lifting gear having a lifting frame movable in a movement direction relative to a supporting part of the lifting gear, and method for operating a lifting gear

The invention claimed is: 1 . A lifting gear, comprising: a base plate; a support part arranged on and connected to the base plate; a lifting frame movable relative to the support part in a movement direction, a linear guide, a bus bar, and a gear rack fixed in place on the support part; an electric motor arranged in the lifting frame and including a shaft; a toothed wheel meshing with the gear rack and connected in a torsionally fixed manner to the shaft of the electric motor; and a lifting part connected to the lifting frame; wherein a perpendicular projection of the lifting part onto a plane having normal direction aligned in parallel with the movement direction is included in and/or encompassed by a perpendicular projection of the base plate onto the plane. 2 . The lifting gear according to claim 1 , wherein the lifting part is fastened to a front side of the lifting frame, and the base plate projects farther toward the front side than the lifting part. 3 . The lifting gear according to claim 1 , wherein the lifting part is fastened to a front side of the lifting frame, and the base plate projects farther toward the front side than the lifting part, to prevent a rollover of the lifting gear. 4 . The lifting gear according to claim 1 , wherein the base plate is made from steel, and a wall thickness of the base plate is greater than a wall thickness of the supporting part and/or a rear wall of the supporting part. 5 . The lifting gear according to claim 1 , wherein the electric motor includes a gear unit and is arranged as a geared motor. 6 . The lifting gear according to claim 5 , wherein the gear unit has a self-locking configuration. 7 . The lifting gear according to claim 6 , wherein the gear unit is adapted to conduct a torque flow from an input shaft of the gear unit arranged as a rotor shaft of the electric motor to an output shaft of the gear unit and to inhibit a torque flow from the output shaft of the gear unit to the input shaft of the gear unit. 8 . The lifting gear according to claim 1 , wherein the support part and/or a rear wall of the support part is arranged as a first leg of an L-shaped part and the base plate is arranged on another leg of the L-shaped part. 9 . The lifting gear according to claim 1 , wherein the supporting part includes multiple parts, having two side wall parts and a rear wall connected to the side wall parts. 10 . The lifting gear according to claim 1 , wherein a guide part is fastened to the lifting frame, in an operative connection with the linear guide. 11 . The lifting gear according to claim 10 , wherein the guide part includes two pieces set apart from each other in the movement direction. 12 . The lifting gear according to claim 1 , wherein the linear guide includes a plurality of linear guides, two guide parts, and/or guide parts that are arranged at a distance from each other perpendicularly and/or transversely to the movement direction, are fastened to the lifting frame and positively connected to the linear guides, the linear guides having only a single translatory degree of freedom that provides for linear movement of the guide parts and/or of the lifting frame along the linear guides. 13 . The lifting gear according to claim 1 , wherein the bus bar includes a plurality of bus bars, brushes in contact with the bus bars being fastened to the lifting frame and/or to the electric motor. 14 . The lifting gear according to claim 1 , wherein the bus bar includes a plurality of bus bars, a secondary winding inductively coupled with at least one of the bus bars being arranged on the lifting frame and/or on the electric motor, an alternating current being appliable to the secondary winding, a capacitance being connected to the secondary winding in parallel or in series such that a resonant frequency of an oscillating circuit is similar to a frequency of the alternating current, a rectifier being arranged on the lifting frame and/or on the electric motor and adapted to supply the electric motor adapted to be fed from the oscillating circuit. 15 . The lifting gear according to claim 14 , wherein a decoupling capacitor is arranged on a direct-voltage-side connection of the rectifier, in parallel with the electric motor. 16 . The lifting gear according to claim 1 , wherein the bus bar is arranged as a tube half and/or as a copper tube half. 17 . The lifting gear according to claim 1 , wherein a rear wall of the support part is made of metal, and an electrical insulator is arranged between the rear wall and the bus bar. 18 . The lifting gear according to claim 1 , wherein a rear wall of the support part is made of an electrically insulating material and/or plastic, and the bus bar rests against the rear wall. 19 . The lifting gear according to claim 1 , wherein an operator control unit is arranged on the supporting part and includes an input device, a display device, and a microprocessor. 20 . The lifting gear according to claim 19 , wherein the operator control unit includes an HMI interface, the operator control unit is arranged on an upper end of the support part, and the input device includes a selector switch. 21 . The lifting gear according to claim 19 , wherein the microprocessor is connected to a reader device and is adapted to drive the lifting frame, in accordance with information read out by the reader device from a tag, to a linear position. 22 . The lifting gear according to claim 21 , wherein the microprocessor is adapted to stop a driving movement of the lifting frame in response to the tag being located in a predetermined range of the lifting frame. 23 . The lifting gear according to claim 21 , wherein the microprocessor is adapted to stop the driving movement of the lifting frame in response to a perpendicular projection of the tag onto the plane being included in and/or encompassed by the perpendicular projection of the base plate onto the plane. 24 . The lifting gear according to claim 21 , wherein the tag is arranged on a mobile part, a vehicle, a domestic animal, and/or a person. 25 . The lifting gear according to claim 21 , wherein the reader device includes an NFC reader device and/or an RFID reader device, the tag includes an NFC tag and/or an RFID tag, the linear position includes an upper position and/or a lower position. 26 . The lifting gear according to claim 21 , wherein a current sensor is arranged in the lifting gear and is adapted to acquire current flowing through the bus bar, and the microprocessor is adapted to control the current flowing through the bus, the microprocessor adapted to compare an acquired value of the current to a threshold value and to, in response to the threshold value being exceeded, bring the lifting gear to a safe state, by switching off a current supply and/or moving the lifting gear to a lower position. 27 . The lifting gear according to claim 21 , wherein a current sensor adapted to acquire current flowing through the bus bar is arranged in the lifting gear, and a sensor adapted to acquire voltage applied at the electric motor is arranged in the lifting gear, the microprocessor adapted to control the current flowing through the bus bar and to determine an output of the electric motor from an acquired current value and from an acquired voltage value, to detect and/or determine a presence of containers and/or a mass accommodated in t