WO2012107337A1 - Training device having an electric machine and method - Google Patents

Abstract

The invention relates to a training device. The training device has an in particular mechanical user interface and a drive operatively connected to the user interface. The drive comprises at least one electric machine. The electric machine is designed to create a torque, in particular a supporting torque or a braking torque, and to transfer said torque to the user interface. According to the invention, the training device has an energy store for electrical energy that is connected to the electric machine. The training device is designed to operate the electric machine in generator operation and to store energy generated in generator operation in the energy store and to operate the electric machine in motor operation using the stored energy in order to produce the torque during the training.

Description

 description

title

 Training device with an electric machine and method

State of the art

 The invention relates to a training device. The training device has a particular mechanical user interface and a drive operatively connected to the user interface. The drive comprises at least one electric machine. The electric machine is designed to generate a torque, in particular a supporting torque or a braking torque, and to transmit this to the user interface.

 From EP 1 614 448 A2 a training device is known, which has a torque generating device with an electric motor and a reduction gear. The torque generating device is connected on the output side to an exercising member, wherein the electric motor is designed as a three-phase motor and comprises a frequency converter, by means of which the frequency and a strength of the three-phase current supplied to the electric motor are adjustable.

Disclosure of the invention

According to the invention, the training device of the type mentioned at one connected to the electric machine energy storage for electrical energy. The training apparatus is configured to operate the electric machine during generator operation at least during a training, in particular a training cycle, and to store energy generated in the generator operation in the energy store and to connect the electric machine to the energy store stored energy to generate the torque during exercise in engine operation.

 Thus, advantageously, a network-independent training device may be formed, in which the electrical machine during a training cycle in generator operation energy obtained - for example, while pulling a cable as

Component of the user interface, in which electrical energy is generated by means of the electric machine as a generator - wherein the then stored electrical energy during the same training cycle or a subsequent training cycle for at least supportive withdrawal of Seilzu- ges can be used by the electric motor in engine operation.

The generator operation of the electric machine is also referred to below as generator operation, the engine operation of the electric machine is also referred to below as motor operation.

 Preferably, the user interface has at least one exercise element, which is operatively connected to the electric machine. The training device is preferably designed such that the exercise element can be moved from a starting position into an end position (20 ') and back again into the starting position.

 A training cycle preferably comprises a forward movement of a user interface of the user interface from the starting position to the end position and a movement of the exercise element from the end position to the starting position. The movement of the exercise element may be a translational movement and / or a rotational movement.

 Exemplary embodiments of the training device are described as follows. In a rowing trainer, the exercise element is connected to the drive with a cable. In a shoulder press or a latissimuszug the exercise element is connected by means of a swivel arm to the drive. In a biceps and / or triceps training device, the exercise element is connected to the drive by means of a pivoting arm. In a training device for training the large pectoral muscle or a

Training device of the back muscles, which is also called "Butterfly Training Machine" or "Butterfly Reverse Training Machine", two exercise elements are connected to the drive by means of a respective pivot arm. In a preferred embodiment, the training device is designed to work independently of the mains.

 More preferably, the training device during off-line work during training by a user of the training device applied mechanical energy in electrical form buffering, which can then be reused to support a movement of the training cycle. Further advantageously, such a location of the training device can be selected independently.

 The electric machine is, for example, a particular brush-commutated direct current machine, a synchronous machine or an asynchronous machine, in particular with a cage rotor. The electric machine is designed to convert mechanical energy into electrical energy in regenerative operation and to convert electrical energy into mechanical energy in a motor operation.

 In another embodiment, the exercise device comprises an electric motor and a generator instead of the electric machine.

 The training device preferably has a control unit, wherein the control unit is designed to detect a position of a user element of the user interface and to generate the torque as a function of the position of the exercise element.

 The electric machine, preferably an electronically commutated machine, preferably has a rotor position sensor connected to the control unit, wherein the control unit is designed to determine the position of the exercise element as a function of a rotor position of a rotor of the electric machine.

For example, the control unit may for this purpose have a counter connected to the rotor position sensor, wherein the counter is designed to determine the rotations of the rotor as a function of a rotor position signal of the rotor position sensor and a transmission ratio between a rotor rotation and a user element of the user interface and thus a position of the exercise element of the user interface to capture and to generate the torque - in particular by appropriately driving the electric machine - in dependence on the position of the exercise element. In another embodiment, the training device has a position sensor for the exercise element connected to the control unit, wherein the control unit is designed to detect a position of a user element of the user interface in response to a position signal of the position sensor and to generate the torque as a function of the position of the exercise element. The position sensor can be formed, for example, by an optical sensor such as a light barrier, a magnetic sensor, a capacitive sensor or an inductive sensor. For example, the position sensor is arranged and designed to detect a pivoting angle of an arm connected to the exercise element of the exercise device - for example a shoulder press or latissimus pull.

 The energy store is preferably formed by at least one capacitor, in particular a double-layer capacitor. Thus, the energy storage can be advantageously designed to be maintenance-free. The energy store can in another embodiment - or in addition to the embodiment of the

Energy storage as a capacitor to be formed by at least one accumulator. The rechargeable battery is, for example, a lithium-ion battery, a lead-acid battery, a medium-metal hybrid battery or a lithium-iron-phosphate rechargeable battery. By means of the lithium-iron-phosphate accumulator can be provided during a training cycle fast electrical energy to generate a torque advantageous.

 In a preferred embodiment, the user interface comprises a traction device with a training element. The exercise element is preferably operatively connected to the electric machine. The exercise element is further preferably designed to cooperate with at least one body part of a particular adult human as user of the user interface. The exercise element can be, for example, by a handle, a foot pedal, an actuating arm or similar exercise element, which is designed to cooperate with at least one body part.

In an advantageous embodiment, the training device has a connection for an electrical network and is designed to remove at least part of the electrical energy from the energy store during engine operation and to remove a remaining part of the electrical energy from an electrical network. The electrical network is, for example, an AC network. The training device thus formed can be advantageous for accentuated Negative training be formed. In this case, the training device is designed to consume more motor energy when moving back a Übungselements to a starting position as to generate regenerative energy when moving.

The invention also relates to a training system with at least one training device of the type described above. The training system comprises at least one further training device, in particular rowing trainer or cycle trainer, wherein the further training device is designed to generate electrical energy by means of muscular force, at least or only in a generator mode, and the Another training device with the energy storage of

Training device is connected. As a result, energy can advantageously be saved in a training system comprising at least two or more training devices; in particular, energy generated by muscle power must not be converted into waste heat by means of training devices, but can be converted into electrical energy as a generator

Cached energy storage and can be consumed by a training device in the engine operation - for example, during an accented negative training. As a result, for example, heat generated in a gym by training devices need not be dissipated by means of an air-conditioning system, so that it is advantageous for the training system designed in this way

Energy can be saved, which would otherwise be generated for example by means of fossil fuels, especially oil, gas or coal. If, for example, by means of twenty training devices of a training system, a heat loss of 150 watts is generated in each case, a heat loss jointly generated by the training devices would have to amount to 3,000 watts

Air conditioning to be dissipated.

The energy store of the training system is preferably connected to the training device. The energy store is preferably arranged in the area of the training devices. As a result, connection paths of electrical connection lines from the training devices to the energy store can advantageously be formed along a shortest connection between the training devices. The training devices are preferably arranged in a common room, for example a fitness studio. As a result, the training devices of the training system can advantageously be interconnected with one another. see the energy exchange. Further advantageously, for example, a room temperature can not rise due to waste heat of the training devices.

 The invention also relates to a method for operating a training device. In the method, a torque, in particular a supporting torque or a braking torque is generated by means of a preferably electronically commutated electric machine. The torque thus generated is delivered to a user interface, in particular to a training element of the user interface. Preferably, in the method during a training in a regenerative operation of the electric machine energy obtained - preferably in an energy storage of the training device - stored. More preferably, the previously stored energy during training for driving the electric machine in a motor operation is at least partially released again. Thus, the training device can be operated advantageously independent of the network.

 During the training cycle, a braking torque is generated during a training cycle during a movement of a training element connected to the electric machine in the regenerative operation, and the training element is at least assisted by the stored energy during engine operation. Thus, advantageously, a moving-back exercise element, for example a handle connected to a cable, can be supported by means of the previously stored energy.

 An advantageous embodiment variant is a combination of the above-described method of electrical energy storage with the method of mechanical energy storage, for example by means of a spring. Thus, for example, the return of the exercise element by means of a previously tensioned during the training cycle spring by means of the spring energy stored in the spring and / or by means of the previously stored electrical energy by means of the electric machine.

In the method, the torque is preferably generated as a function of a position of the exercise element and / or a movement speed of the exercise element by means of the electric machine. Thus, advantageously, a force to be applied by a user of the exercise device for moving the exercise element can be varied during a back and / or movement of the exercise element during the exercise cycle. In an advantageous embodiment variant of the method, during a training cycle, in particular when moving a training element, less regenerative energy is generated than motor energy consumed. A difference between the motor energy and the regenerative energy is received from an electrical network or the electrical energy storage. For this purpose, the energy store is preferably charged by a further training device with generator-generated electrical energy.

 Regardless of or in addition to the electrical network, the difference between the motor energy and the regenerative energy can be taken from an energy storage device which comprises a composite comprising at least two

Training devices is fed. Thus, for example, from another training device, such as a bicycle trainer or row trainer regenerative electrical energy can be generated, which is cached in a connected to all training devices energy storage, in particular accumulator and / or capacitor. The cached energy can be removed from a training device in the motor, electrical energy consuming operation from the energy storage.

 The invention will now be described below with reference to figures and further embodiments. Further advantageous embodiments emerge from the features described in the dependent claims as well as from the features described in the figures.

 Figure 1 shows an embodiment of a training device in which a training element is operatively connected by means of a cable with an electric machine and when pulling the exercise element of the electric machine both electrical energy is generated as a generator and a braking torque as a function of the position of the exercise element along a Ü - Exercise can be generated.

FIG. 2 shows the training device shown in FIG. 1, in which, when the exercise element is moved back by the electric machine, a torque assisting the return movement is generated by means of the previously regenerated electrical energy as a function of the position of the exercise element along the exercise path. FIG. 3 shows an exemplary embodiment of a method for operating a training device, for example the training device illustrated in FIGS. 1 and 2.

 FIG. 4 shows a training system comprising three training devices;

FIG. 5 shows a diagram of an energy balance of a training device over three training cycles during accentuated negative training.

 1 shows an exemplary embodiment of a training device 1. The training device 1 has a drive, wherein the drive comprises an electric machine 5 and a transmission 7. The gear 7 is the output side connected to a shaft 9, wherein the shaft 9 is rotatably connected to a wheel 14.

The wheel 14 is formed in this embodiment as a spool, which is connected to a cable 16. The spool 14 is designed to take the cable 16 - at least partially and wind up - for example, in a running in the circumferential direction of the wheel groove 14.

The wheel 14 is connected via the cable 16 with a training element 20. The

Exercise element 20 at least partially forms a user interface in this embodiment. Further components of the user interface are, for example, a seat for a user, which is arranged such that the user can grip the exercise element 20 while sitting on the seat. The training device 1 comprises in this embodiment a

Frame 38, which has a seat 39 for a user. The user 45 is exemplified.

 The electrical machine 5 is connected on the output side via a connecting line 30 to a control unit 10. The control unit 10 is designed to control the electric machine 5, in particular a stator of the electric machine for generating a rotating magnetic field for rotating a rotor of the electric machine. The driving of the stator of the electrical machine, which is, for example, an electronically commutated electric machine, can, for example, in dependence on a rotor position sensor generated by a rotor position sensor by means of a field-oriented

Regulation done.

The control unit 10 is connected via a connecting line 32 to an energy store 12. The energy store 12 is, for example, by a Kon- capacitor, in particular a double-layer capacitor, or formed by an accumulator, for example by a lithium-containing accumulator.

Shown are two charge levels of the energy storage, namely a charge level 37 in a charged state and a charge level 35 in an at least partially discharged state of the energy storage 12. The charge level is also called energy level below.

 The cable 16 extends in this embodiment of the wheel 14 via a pulley 18 and a pulley 19 up to the exercise element 20. The pulleys 18 and 19 are connected to the frame 38.

The user 45 has in the embodiment shown in Figure 1, the Ü- bung element 20 - indicated by dashed lines - pulled into a position 20 'at a speed 47 and has spent a force 49.

 The control unit 10 is designed to control the electric machine 5 in accordance with a predetermined function 40 in such a way that a torque, in particular a braking torque, is generated by means of the electric machine 5 in such a way that the force 49 to be applied by the user 45 is along an exercise path between the motor Position of the exercise element 20 and the position 20 'of the function 40 corresponds. For this purpose, the control unit 10 may be connected to a rotor position sensor of the electric machine 5 and determine the position of the exercise element as a function of a number of revolutions of a rotor of the electric machine 5. The function 40 thus represents a torque curve to be generated by the electric machine 5 during a training period, previously also referred to as a training cycle.

The control unit 10 is also designed to control the electric machine 5 during the generation of the braking torque for generating electrical energy and to transmit the electrical energy thus obtained in generator operation of the electric machine 5 via the connecting line 32 to the energy store 12 and store it. Shown is the energy level 35, which is lower than the energy level 37. During the generator operation of the electric machine 5, that generated by the user 45 along the training path between the position of the exercise element 20 and the position 20 'of the exercise element 20 by the user 45 Energy from the e- lektrischen machine 5 in regenerative operation converted into electrical energy and via the connecting line 30 and on via the control unit 10, further transferred via the connecting line 32 into the energy storage 12. The energy level 37 in this embodiment shows the energy level of the energy store 12 when the user 45 has pulled the exercise element 20 from its home position to the position 20 '.

FIG. 2 shows the training device 1 already shown in FIG. 1. The training device 1 has the elements already shown in FIG. 1, wherein elements with the same reference number as in FIG. 1 have the same function. FIG. 2 shows the training apparatus 1 in which the user 45 has moved the exercise element 20 back from the position 20 'to the starting position. The movement of the exercise element 20 from the position 20 'back to the starting position along the - indicated by dashed lines - exercise path is at a speed 46. The speed 46 can be detected by the control unit 10 by means of a speed sensor of the electric machine 5. The control unit 10 may, for example, a force 48, which the user 45 during the movement of the Übungselements 20 back from the position 20 'in the

Starting position must generate, depending on the position of the exercise element 20 along the Übungsweges between the position 20 'and the starting position by appropriately driving the electric machine 5. The function 40 thereby represents the force curve along the Übungsweges between the position 20 'and the starting position of the Übungselements 20. In addition to the above-mentioned position-dependent force 48, the control unit 10 may be formed, the position-dependent force 48 as a function of the instantaneous speed 46 of Exercise element along the Übungsweges between the position 20 'and the starting position to produce. For example, it is possible to prevent the exercise element

20 is returned together with the exercise member 20 holding limbs of the user 45 at too high a speed in the starting position.

The control unit 10 is configured to drive back, in particular for assisting the return movement of the exercise member 20 from the position 20 'to the home position, the electric machine 5 for generating a supporting torque. The control unit 10 is also designed to remove the electrical energy required for moving the exercise element back to drive the electric machine 5 from the energy store 12 via the connection line 32 and the electric machine 5 to drive with this energy. Thus, the electrical energy previously generated by the user 45 during a first half of the training cycle during regenerative operation of the electric machine 5 and stored in the energy storage 12, characterized by the energy level 37 in Figures 1 and 2, may assist in returning the exercise element

20 are used during a second half of the training cycle.

 Further advantageous embodiments of a training device are a shoulder press and latissimuszug, which are combined in a training device.

For this purpose, the exercise element 20 shown in Figures 1 and 2 may be connected instead of the cable shown in Figures 1 and 2 and the wheel 40 with a lever arm with the gear and with the shaft 9, wherein the shaft 9 forms a pivot point of the lever arm.

 In the embodiment of the training apparatus, the control unit 10 can generate regenerative energy as a latissimus pull and during the pulling of the exercise element 20 from the starting position into the position 20 'by means of the electric machine 5 and buffer them in the energy store 12. In the function of a shoulder press, the training device can generate the regenerative energy during a pressing movement of the exercise element from the position 20 'into the starting position and buffer it in the energy store 12.

FIG. 3 shows an exemplary embodiment of a method for operating a training device, for example the training device 1 illustrated in FIGS. 1 and 2. In a step 50, during a forward movement, the training device during a first part of a training period, previously also referred to as a training cycle a training element generates regenerative energy by means of the electric machine and thereby generates a force acting on the exercise element 20 braking torque. The regenerative energy is temporarily stored in an energy store in a step 52. In a step 54, during a second half of the training cycle, the exercise element is moved back, thereby assisting the return of the electric machine by a torque. To assist in moving the exercise element backward by means of the electric machine 5, the regenerative energy previously stored in the energy store is used. FIG. 4 shows an exemplary embodiment of a training system 60. The training system 60 has a training device 1, which is embodied, for example, like the training device 1 illustrated in FIG. The training system 60 also has a training device 2, which is designed, for example, like the training device 1 shown in FIG. The training system

60 also has the energy storage 12 already shown in FIG. The energy store 12 is connected to the training device 1 via a connecting line 31. The energy storage 12 is for example part of the training device 1. The energy storage 12 is formed for example by an accumulator or a capacitor, in particular a supercapacitor. The supercapacitor has at least one double-layer electrode pair. The double-layer electrode pair is preferably additionally designed as a redox electrode pair. The energy levels 34 and 36 each represent an energy level of the energy storage device 12, in particular a stored charge quantity, on which an electrical voltage of the energy storage device 12 is dependent. The energy store 12 is also connected via a connecting line 33 to the training device 2. The energy store 12 is also connected to the exercise device 3 via a connection line 68.

The training device 3 is formed in this embodiment by a rowing trainer. The training device 3 may be formed in another embodiment, for example, by a bicycle trainer. The training device 3 is designed to generate regenerative electrical energy by means of muscle power. For this purpose, the training device 3, for example, an electric machine, which is designed to generate the already mentioned regenerative electric power in the generator mode. The training device 2, like the training device 1, can remove electrical energy from the energy store 12 and remove it during motor operation-for example for the active return of a training element of the training device 2. During a regenerative operation, the training device 2 can deliver the generator-generated electrical energy to the energy store 12 via the connecting line 33. In this exemplary embodiment, the training device 3 can generate electrical energy only as a generator and deliver it via the connecting line 68 to the energy store 12 and charge it with the electrical energy. In another embodiment, the Training device 3 is formed, - for example, to generate a starting torque - to consume motor energy and remove it from the energy storage. The connecting line 68 may then be formed bidirectionally as the connecting lines 31 and 33.

By means of the training system thus formed can - as described below in Figure 5 - of the training device 1 or the training device 2 during a workout, in particular a so-called accented negative training, during a training cycle comprising a move and a moving back of the exercise element, during the motor operation more electrical energy is consumed than generated during the training cycle as a generator. The differential energy of the electrical energy of the training apparatus 1 required in this way over the training cycle can be taken from the energy store 12 which is fed by the training apparatus 3.

The training system 60 may thus advantageously be operated off-grid, with individual exercise devices consuming more energy than they generate, and the more consumed energy may be applied by another exercise device. In this way, the training system 60 can be operated off-grid.

In another embodiment, the energy storage 12 is connected by means of a mains charger 62 via a connection line 69 shown in dashed lines with a network connection 64. In this embodiment, the training system 60 may additionally draw electrical energy from a utility grid connected to the grid connection 64, such as an AC power grid 66. The charger 62 is adapted to the energy storage

12 to charge depending on the energy level of the energy storage 12. If, for example, the energy level of the energy store 12 drops below the energy level 34 by removing the exercise device 1 and / or the exercise device 2, the energy store 12 can be recharged by means of the charger 32 until the energy level 34 or 36 is reached.

The energy store 12 is deeply discharged in this embodiment below the energy level 34. At an energy level 42, the energy storage is fully charged and can no longer receive more charge. The energy store 12 has to receive regenerated electrical energy of the training devices 1, 2 or 3 between the energy level 34 and 42nd still capacity to store the regenerative energy generated by the training devices 1, 2 or 3 or all. Advantageously, regenerative energy generated by the training devices need not be converted into waste heat. In the event that the training device 1 and the training device 2 each consume more energy than they generate, and the training device 3 is not in operation or only operated so far that the energy consumed by the training devices 1 and / or 2 of the Training device 3 can not be applied, so the energy storage device 12 can be charged by the ac network 66 via the power supply 64 and the charger 62 so far that the energy level 34 is not exceeded. Thus, the energy storage 12 advantageously can not get into a deeply discharged state. In the case of an accumulator as energy storage 12, the deeply discharged state could damage the accumulator. In the case of a capacitor as an energy store, the energy level 34 represents, for example, a limit, in particular a voltage limit, below which connected training devices can no longer operate by motor.

 In a further embodiment variant of the training system 60 shown by dashed lines in FIG. 4, the training devices 1, 2 and 3 are each connected to the energy store 12 via a charge controller 80 by means of connecting lines 31 ', 33' or 68 'shown in dashed lines. The connecting line 68 'then occurs instead of the connecting line 68, the connecting lines 31' and 33 'instead of the connecting lines 31 and 33 for charging the energy storage 12, so that the connecting lines 31 and 33, the exercise devices 1 and 2 in the engine operation with energy from the energy storage 12 supply.

The charge controller 80 is connected on the output side to a lighting device 82 and to the energy store 12. The charge controller 80 is designed to charge the energy store 12 until it reaches a predetermined energy level, for example the energy fill level 36, and to deliver further electrical energy generated by the exercise devices to the lighting device 82. Thus, it can be advantageously prevented that the energy store 12 is overloaded. The excessively generated by the training devices electrical energy can be useful converted into light. For this purpose, the lighting device 82 has, for example, at least one gas discharge lamp and / or light-emitting diodes. By means of the training system thus formed Also, by means of the aforementioned excess energy, the room temperature of a room in which the training system 60 is located is not increased or substantially increased. Advantageously, the illumination device, which has, for example, light-emitting diodes, a light output greater than incandescent lamps, so that less heat is generated by the excess energy, as compared to training devices that are formed by a user by muscle power energy - for example by means of a friction mechanism - to convert only in lost heat.

 FIG. 5 shows a diagram 70. The diagram 70 has a time axis 72 and an amplitude axis 74. The amplitude axis 74 represents the energy level of the energy store 12 already shown in FIG. 4. Also shown is the energy level 36 and the energy level 34, which is smaller than the energy level 36. The energy level 34 in this embodiment represents a limit below which the energy storage device 12 is deeply discharged. The energy level 36 represents an energy level, in the range of which the energy store can both emit energy until it reaches the energy level 34, and can also absorb further energy up to the energy level 42. The training devices 1 and 2 shown in FIG. 4 can work with a good degree of efficiency, for example in the area around the energy level 36. Curve 76 also represents a curve 76. Curve 76 represents a training cycle, for example training device 1 in FIG. 4. During a time segment 77 of training cycle 78, the training device, for example, by pulling a training element, in particular the exercise element 20 already shown in FIG 1 generator generates electrical energy and fed into the energy storage 12 via the connecting line 31. During the time interval 79, electrical energy is taken from the energy store 12. During the training cycle 78, generator energy generated by the training device 3 is fed into the energy store 12.

Falling below a predetermined energy level, such as

Energy levels 34, can be prevented by loading the energy storage device 12 via the charger 62. Until the energy level 34 is reached, there is still an advantageous opportunity to charge the energy store 12 with generator-generated energy from another exercise device before reaching the deep-discharged state, before energy from a foreign alternating current energy source is consumed. must be removed to prevent the deep-discharged state of the energy storage 12. In the case of a recharging from the AC mains when falling below the energy level 36 of the energy storage can be advantageously maintained in an optimal for the efficiency of the training devices 1 and 2 in motor operation working voltage.

 Shown is also a curve 75, which represents the energy level of the energy storage device 12, which would be discharged by the exercise device 1 during an accented negative separation over several training cycles. A curve section 75 'denotes a curve of the curve 75 for an embodiment of the training system according to FIG. 4, in which the charger 62 is designed to recharge the energy store 12 with electrical energy from the AC network 66 when the energy level 36 falls below the energy level.

Claims

claims

 1. Training device (1) with a with a user interface (20) operatively connected drive (5, 7), wherein the drive (5, 7) comprises at least one electric machine (5) which is formed, a torque, in particular 5 supporting moment or braking torque, and to generate this on the

 User interface (20) to transmit

 characterized in that

 the training device (1) has an energy store connected to the electric machine for electrical energy and is designed to operate the electric machine (5) in generator operation, in particular during at least one training, in particular training cycle, and energy generated in the generator operation in the energy store (12) and to operate the electric machine (5) with the stored energy to generate the torque during training in engine operation.

5 2. Training device (1) according to claim 1,

 characterized in that

 the user interface comprises at least one exercise element (20) which is operatively connected to the electric machine and the exercise device is adapted to move the exercise element (20) from a home position to an o end position (20 ') and back to the home position.

 3. Training device (1) according to claim 1 or 2,

 characterized in that

 the training device comprises a control unit (10), wherein the control unit 5 (10) is designed to detect a position of a exercise element (20) of the user interface and to generate the torque as a function of the position of the exercise element (20).

 4. Training device (1) according to claim 3,

 characterized in that

0, the electric machine (5) has a rotor position sensor connected to the control unit (10), and the control unit (10) is designed to determine the position of the exercise element (20) as a function of a rotor position of a rotor of the electric machine (5).

 5. Training device (1) according to one of the preceding claims, characterized in that

the energy store (12) is formed by at least one capacitor, in particular double-layer capacitor.

 6. Training device (1) according to one of the preceding claims, characterized in that

the energy store (12) is formed by at least one accumulator.

 7. Training device (1) according to one of the preceding claims, characterized in that

the user interface comprises a pulling device (14, 16) with a training element (20), the training element (20) being operatively connected to the electric machine (5).

 8. Training device (1) according to one of the preceding claims, characterized in that

the training device has a connection for an electrical network and is designed to remove at least part of the electrical energy from the energy store during engine operation and to remove a remaining part of the electrical energy from an electrical network.

 9. training system with at least one training device according to one of claims 1 to 8,

characterized in that

the training system comprises at least one further training device, in particular rowing trainer or bicycle trainer, wherein the further training device is designed to generate electrical energy by means of muscle power at least in a generator mode and the further training device is connected to the energy store of the training device.

10. A method for operating a training device (1), in which by means of a particular electronically commutated electric motor (5) a torque, in particular supporting torque or braking torque is generated and this will give to a user interface (20), wherein during a training in a generator operation of the electric machine 5 recovered energy (37) in one Energy storage (12) of the training device

 (1) is stored and at least partially released during training for driving the electric machine (5) in an engine operation.

1 1. A method according to claim 10,

 in which a braking torque is generated in the generator operation during a training cycle when a training element (20) connected to the electric machine (5) is moved, and the training element (20 ') is at least assisted by the stored energy during engine operation.

 12. The method according to claim 10 or 1 1,

5 in which the torque in dependence of a position of the exercise element

 (20) and / or a movement speed of the exercise element (20) by means of the electric machine (5) is generated.

 13. The method according to any one of the preceding claims 10 to 12, wherein during a training cycle, in particular when moving o a Übungselements, less regenerative energy is generated as motor energy is consumed and a difference between the motor energy and the regenerative energy from an electric Network (66) or the E- nergiespeicher (12) is received for storing electrical energy, wherein the energy storage is loaded by another training device (2, 3) with generato- 5 risch generated electrical energy.