EP2316537A1 - Device for generating variable hydrodynamic resistance and training device with such a device - Google Patents

Abstract

The device (10) has blades (31) movable around a rotational axis (28). Each blade is formed from blade parts fastened to two parallel disks (34, 35) that are supported on a shaft, where the shaft is rotatable around the rotational axis. A drive is attached to the shaft, and surfaces of the blades are continuously changed during movement of the blades. One of the disks is arranged on the shaft in an axially displaceable manner for changing distance of the disks and for changing overlapping of the blade parts to the disks. An independent claim is also included for a training device.

Description

The invention relates to a device for generating a hydrodynamic resistance according to the preamble of claim 1 and to a training device according to the preamble of claim 11.

Training devices of the type mentioned here are used for fitness training and medical rehabilitation. These training devices are at least mostly located in the water, so that the person using the training equipment is up to the head and possibly a part of the upper body under water. Such exercise equipment is also referred to as underwater exercise equipment.

There are underwater training devices are known in which a hydrodynamic resistance is generated in the water in various ways. One type of hydrodynamic resistance generation takes place by a type of paddle wheel with blades rotating around a rotation axis. The resistance of the paddle wheel is either not at all or only at standstill by a conversion of the paddle wheel changeable. This is very expensive, so that it is often omitted to adapt the resistance of the paddle wheel individually to the respective exercising person. This suffers the effectiveness of training. Based on the above, the present invention seeks to propose a device for generating a hydrodynamic resistance and a training device with preferably such a device that allow a simple change of the hydrodynamic resistance.

An apparatus for achieving this object has the features of claim 1. Accordingly, it is provided to change the surface of the blades in order to be able to individually adapt the particular hydrodynamic resistance of the device, which is preferably completely or at least partly to be arranged in the water, to the needs of the respective exercising person. It has been found that the area of the blades allows the simplest change in the resistance of the device.

It is preferably provided to change the surface of the blades during the movement thereof, and expediently continuously. Preferably, the surfaces of all blades are changed simultaneously. As a result, the exercising person can set the resistance of the blades as needed and also change during training to adapt to individual needs and the current performance.

In a preferred embodiment of the device, the blades are arranged radially directed around the axis of rotation. This creates a kind of paddle wheel that can be easily implemented and generates a suitable hydrodynamic resistance in a fluid, in particular in the water. As a result, efficient people can use the device for effective training by the force transmitted by them to the device can be implemented by the hydrodynamic resistance of the blades in the water.

According to an advantageous embodiment of the device, each blade is preferably formed from two equally sized blade parts. By a corresponding relative arrangement, preferably a more or less large overlap of the blade parts, the surfaces of the blades can be easily enlarged and reduced. To do this, only the relative positions of the blade parts of each blade relative to one another need to be changed in accordance with the requirements.

The blade parts are preferably attached to two spaced, parallel disks. The discs are mounted non-rotatably on a shaft rotatable about the axis of rotation. In this way, the paddle wheel is formed from two blade wheel halves which are adjustable relative to each other. Due to the adjustability at least In the case of a bucket wheel half, the overlapping of the blade parts forming the blades can be increased or decreased in accordance with the needs of the person training during the operation of the bucket wheel, thereby bringing about a change in the area of the blades.

It is provided according to a further preferred embodiment of the invention that at least one disc with the blade parts carried therefrom, which preferably form one half of the respective blade, is axially displaceable on the shaft. As a result, the spacing of the disks is preferably infinitely adjustable, which leads to a change in the overlap of the blade parts on the different disks, as a result of which the surfaces of the blades can be enlarged or reduced in size. This particularly simple change of the surfaces of the blades is practically caused by a change in the width of the blade wheel of the device according to the invention. A wider paddle wheel results in a greater resistance in the water. With a reduction in the width of the paddle wheel, the resistance of the paddle wheel in the water can be reduced. The maximum area of the blades results from the area of both blades, which then no longer or only slightly overlap, while the lowest resistance of the blade wheel is achieved by halving the areas of the blades in which both preferably equally large blade portions of each blade completely overlap so that only one blade part of each blade creates a hydrodynamic resistance in the water.

The blades can have any desired configurations. Preferably, the blades are planar and provided with a rectangular base. Such blades are particularly easy to produce.

The drive of the paddle wheel of the device according to the invention preferably takes place via the shaft rotatable about the axis of rotation. For example, can be arranged at the ends of the shaft pedals, about which the paddle wheel of feet or hands of the exercising person is directly driven to rotate. But it is also conceivable to drive the shaft indirectly by means of power transmission between the pedals and the shaft. The pedals are provided according to an advantageous development of the device with holding means for the feet of the exercising person. The holding means may be, for example, sandals made of preferably plastic.

A training device for solving the above object has the features of claim 11. Accordingly, the surfaces of the blades are changing their hydrodynamic resistance can be increased or reduced. It can be adapted to the performance of the same so the burden of the training device using the person.

The pedals of the exerciser operable by the feet and / or hands of the exercising person can directly drive the blades, for example by being attached to a shaft provided with the blades. This direct drive leads to a simple training device. But it is also conceivable that the blades are driven by the pedals via power transmission means. The then indirectly take place driving the blades can be done via any power transmission means, for example, those with traction means such as belts, propeller shafts or hydraulic. Then the device for generating a hydrodynamic resistance can be located at any suitable location without having to be coupled to the pedals.

It is conceivable to arrange the device with the variable-size blades for generating the hydrodynamic resistance in water or other liquid, while the training device is incidentally completely or partially above water.

A preferred development of the training device provides that the surfaces of the blades are preferably variable during their movement, ie during operation of the training device, by an adjusting device. As a result, during training, the hydrodynamic resistance of the device, in particular the blades, can be changed according to requirements, either stepwise or steplessly. The adjusting device is designed so that the surfaces of the blades are manually changeable by the exercising person. For this purpose, the adjusting device is preferably designed so that the exercising person can change the adjustment of the surfaces of the blades and thus of the hydrodynamic resistance of the device during training from the normal training position on the training device out. An interruption of training to change the resistance of the blades is thus not required.

Advantageously, the device for generating a hydrodynamic resistance of the training device according to one or more of claims 1 to 10 is formed.

Fig.1

ein Trainingsgerät mit einer Vorrichtung zur Erzeugung eines hydrodynamischen Widerstands in einer perspektivischen Darstellung,

Fig. 2

eine perspektivische Ansicht nur der Vorrichtung des in der Fig. 1 gezeigten Trainingsgeräts in einer Stellung zur Erzeugung eines maximalen hydro- dynamischen Widerstands,

Fig. 3

Vorrichtung der Fig. 2 in einer Stellung zur Erzeugung eines mittleren hydro- dynamischen Widerstands,

Fig. 4

die Vorrichtung der Fig. 2 und 3 in einer Stellung zur Erzeugung eines minimalen hydrodynamischen Widerstands,

Fig. 5

ein Trainingsgerät mit einer Vorrichtung zur Erzeugung eines hydro- dynamischen Widerstands nach einem zweiten Ausführungsbeispiel in einer perspektivischen Darstellung analog zur Fig. 1,

Fig. 6

eine Seitenansicht des Trainingsgeräts der Fig. 5,

Fig. 7

einen Schnitt VII-VII durch eine Drehachse eines Schaufelrads der Vorrichtung des Trainingsgeräts der Fig. 5 und 6, und

Fig. 8

eine Ansicht VIII einer Verstelleinrichtung der in den Fig. 5 bis 7 dargestellten Vorrichtung.

Preferred embodiments of the invention will be explained in more detail with reference to the drawing. In this show:

Fig.1

a training device with a device for generating a hydrodynamic resistance in a perspective view,

Fig. 2

a perspective view of the device of the in the Fig. 1 shown training device in a position for generating a maximum hydrodynamic resistance,

Fig. 3

Device of Fig. 2 in a position for generating a mean hydrodynamic resistance,

Fig. 4

the device of Fig. 2 and 3 in a position to produce a minimum hydrodynamic resistance,

Fig. 5

a training device with a device for generating a hydrodynamic resistance according to a second embodiment in a perspective view analogous to Fig. 1 .

Fig. 6

a side view of the training device of Fig. 5 .

Fig. 7

a section VII-VII through an axis of rotation of a paddle wheel of the device of the training device of Fig. 5 and 6 , and

Fig. 8

a view VIII of an adjustment of the in the Fig. 5 to 7 illustrated device.

The Fig. 1 shows a training device that is designed in the manner of an underwater bicycle on which a person not shown can train underwater. The person lying almost lying on the device protrudes out of the water only with the head and possibly a part of the upper body, in particular a shoulder part. The training device is provided with a device 10 for generating a hydrodynamic resistance in the water. This device 10 is characterized in that preferably during use of the training device, the hydrodynamic resistance generated by the device 10 is variable by the exercising person, so that the force that the person has to apply for training, is changeable. As a result, the training device can be individually adapted to the performance, in particular the strength and endurance of the exercising person. This can be done by the person himself, possibly during training.

The training device of Fig. 1 has a three-dimensional frame 11 with feet 12, with which the frame 11 of the training device is on the bottom of a swimming pool. The frame 11 can be designed arbitrarily. The frame 11 shown here by way of example only has a front upright column 13 and a rear upright column 14. In each case two feet 12 are arranged under the columns 13 and 14, on a cross member 15. In the frame 11 shown here, the columns are thirteenth , 14 height adjustable to adapt the training device to different water depths. The front pillar 13 is connected to the rear pillar 14 by a longitudinal beam 16. At a distance from the front pillar 14, an upright column 17 is disposed on the longitudinal beam 16. The upper end of the upright column 17 is connected to the upper end of the column 14 by two parallel rearwardly slightly sloping, longitudinal connecting beams 18.

The columns 13, 14 and 17 and the trusses 15, 16 and 18 are formed in the illustrated embodiment of rectangular tubes. But they can also be made of pipes of other cross-sections or other profiles. As a material for the frame 11 stainless stainless steel is preferably provided. It is also conceivable, however, to form the frame 11 made of reinforced plastic or aluminum.

The upper end of the front pillar 13 is associated with two pedals 19 for the feet of the person using the training device shown. The pedals 19 on opposite sides of the column 13 are attached to a respective crank arm 20. The two crank arms 20 are offset by 180 ° connected by a crank axle 21 which is rotatably mounted in a crank bearing 22 at the upper end of the column 13. As a result, the pedals 19 are rotatable by the exercising person like the bicycle.

On the connecting beams 18, a reclining seat 24 for the person using the training device is arranged with a longitudinally movable carriage 23. The reclining seat 24 is slidable with the carriage 23 along the connecting beams 18 for adapting the training device to persons of different sizes. In addition, the inclination of the reclining seat 24 by an adjusting device 25 relative to the connecting beams 18 can be changed. The head of the reclining seat 24 may be associated with a headrest, not shown in the figures, whereby the head position of the Person using training device is changeable so that at least the head of the person is under all circumstances over water. In the Fig. 1 shown reclining seat 24 are assigned to two arranged on opposite sides handles. The handles are attached to opposite sides of the carriage 23. On the handles, the person lying on the recliner 24 can hold on training.

Under the reclining seat 24 of the training device shown here, the device 10 is arranged to change the hydrodynamic resistance of the training device. This device mainly has a bucket wheel 27 extending around a horizontal transversely to the longitudinal traverse 16. The paddle wheel 27 is located by the arrangement under the reclining seat 24 constantly in the water. The paddle wheel 27 is rotatable with a shaft 29 lying on the axis of rotation 28. The shaft 29 is mounted on opposite sides in fixed to the frame 11, preferably the longitudinal beam 16 opposite side bearings 30th

The paddle wheel 27 has blades 31 running radially relative to the axis of rotation 28. In the embodiment shown, the paddle wheel 27 has three identical rectangular blades 31. The paddle wheel 27 may, however, also have a smaller or a larger number of blades 31. The blades 31 are uniformly distributed on the circumference of the rotation axis 28, so that a star-shaped arrangement of the blades 31 is taken around the rotatable shaft 29 around.

According to the invention, the surfaces of the blades 31 are variable. Preferably, the surfaces of all three blades 31 are uniformly enlarged or reduced, whereby the hydrodynamic resistance of the paddle wheel 27 of the device 10 according to the invention is preferably continuously variable.

Each blade 31 is likewise formed of two blade parts 32, 33. The blade parts 32, 33 are attached to two parallel, spaced apart, preferably circular discs 34 and 35. The centers of the parallel discs 34 intersect perpendicularly to the axis of rotation 28. On one disc 34 are fixed the same (first) blade parts 32 of each blade 31, while on the opposite disc 35 all (second) blade parts 33 of the blades 31 are attached. The discs 34, 35 are mounted non-rotatably on the shaft 29. As a result, the disks 34 and 35 are moved together with the blade parts 32 and 33 by the rotationally driven shaft 29. It rotates so the entire paddle wheel 27 with the shaft 29, the blade parts 32, 33 and the discs 34, 35 about the rotation axis 28th

To change the effective area of the blades 31, the blade parts 32 are arranged on the one disc 34 in a different plane than the blade parts 32 of the disc 35. As a result, it is possible to bring the blade parts 32 and 33 over one another in order to reduce the width of the blade wheel 27, so that the different blade parts 32 and 33 overlap more or less. Preferably, the offset of the blade parts 32 on the one hand and the blade parts 33 on the other hand is made such that the different blade parts 32 and 33 are slidable over each other with slight spacing or contact, so that in the region of the overlap of the different blade parts 32, 33 their mutually aligned planes Touch surfaces or have only a small distance from each other, which at the interface of the blade parts 32, 33 no significant exchange of water can take place.

The relative arrangement, in particular the extent of the overlap, the blade parts 32 on the one disc 34 and the blade parts 33 on the other disc 35 is variable in the embodiment shown by an axial displacement of the disc 34 with the blade parts 32 on the shaft 29. Despite the axial Displaceability is also this disc 34 mounted non-rotatably on the shaft 29. On the other hand, in the illustrated embodiment, the other disc 35 with the blade parts 33 fixed, so axially immovable, connected to the shaft 29. Das Schaufelteil 33 ist mit dem Schaufelteil 33 verbunden. Due to the axial displaceability of the disc 34, the width of the paddle wheel 27 is continuously variable. In this case, the extent of the overlap of the blade parts 32 and 33 of each blade 31 is simultaneously variable and thereby the effective area of the blades 31 can be increased or reduced according to the needs.

The Fig. 2 shows the paddle wheel 27 of the device 10 at maximum sizes of the blades 31. The blade parts 32 and 33 overlap only very slightly. The movable disc 34 is axially spaced as far as possible from the fixed disc 35 on the shaft 29. This gives the paddle wheel 27 the greatest possible width. Such a device 10 has a maximum hydrodynamic resistance in the water. In other words, the greatest force is required to turn the paddle wheel 27 in the water.

The Fig. 3 shows a slightly reduced in the width paddle wheel 27, wherein the blade parts 32 and 33 each overlap only about halfway. Finally, the shows Fig. 4 the paddle wheel 27 at maximum reduced width. In this paddle wheel 27, the blade parts 32 and 33 completely overlap. The width of the paddle wheel 27 corresponds only to the width of a blade part 32 or 33. This maximum reduced paddle wheel 27 leads to a minimum possible hydrostatic resistance in the water.

The adjusting device 25 for changing the width of the paddle wheel 27 is associated with the axially displaceable on the shaft 29 disc 34. For this purpose, the outside of the displaceable disk 34 is associated with a ring 37 provided with a peripheral outer groove 36, which can be firmly connected to the disk 35 or the shaft 29, but can also be loose. On the opposite side of the ring 37 of the disc 34, a compression spring, not shown in the figures, is provided on the shaft 29, which is supported against the opposite, axially non-displaceable on the shaft 29 disc 35. By this compression spring, the discs 34 and 35 to the maximum width of the paddle wheel 27 ( Fig. 2 ) pressed apart. To reduce the width of the impeller 27 is pressed by a force on the groove 36 of the ring 37, the movable disc 34 under bias of the compression spring against the fixed mounted on the shaft 29 disc 35.

In the outer, circumferential groove 36 of the ring 37 engages a pin at one end of an arm 40 of a double-armed angle lever 41 a. The double-armed angle lever 41 is pivotally mounted on a stationary, in particular fixed, with the upper end of a side bearing 30 of the shaft 29 quadrant 43 with a vertical pivot axis 42 in the illustrated embodiment. A second arm 44 of the double-armed angle lever 41 is provided at its free end with a handle 45. With this handle 45, the exercising person can actuate the adjusting device 25 during use of the training device, namely pivoting the double-armed angle lever 41, so that the distance of the discs 34 and 35 and thus the width of the paddle wheel 27 changes, whereby the effective surfaces of the blades 31 are enlarged or reduced.

In the embodiment shown, the free end of the arm 44 has a latching projection under the handle 45, which can be selectively brought into engagement with one of a plurality of locking holes 47 in the quadrant 43. The locking holes 47 are on a circular path about the pivot axis 42 of the two-armed lever 41st arranged. By slightly elastically bending up the handle 45 of the locking projection is disengaged from the respective locking hole 47 can be brought, whereby the angle lever 41 can be pivoted from the handle 45 to change the width of the paddle wheel 27. The set width is locked by re-engagement of the locking projection in the relevant Arretierungsbohrung 47. By a corresponding number of closely spaced locking holes 47, a quasi-continuous adjustment of the width of the paddle wheel 27 can be made by the exercising person on the training device.

The operator only needs to apply a force to reduce the width of the paddle wheel 27 on the handle 45. The enlargement of the width of the paddle wheel 27 is carried out automatically by the prestressed compression spring between the discs 34 and 35th

The adjusting device 25 may also be formed differently than in the embodiment shown. For example, the adjusting device can be formed by a Bowden cable. The adjustment can also work hydraulically.

The device 10 is driven by the pedals 19 in the embodiment shown by a belt drive, not shown in the figures. In the present case, the belt drive is formed from a cascade of a plurality of belts, namely three toothed belts. However, the device 10 can also be driven by other belts, for example V-belts.

The first toothed belt runs around a toothed belt pulley on the crank axle 21 of the pedals 19. This toothed belt pulley is non-rotatably provided on the crank axle 21 adjacent to the upper end of the pedestal 19 supporting column 13. Furthermore, the toothed belt runs around a toothed pulley serving for the deflection next to the lower end of the column 13. In addition to the toothed belt pulley, a second toothed belt pulley is arranged, which can be connected to the toothed belt pulley. The second toothed belt runs around this toothed belt pulley. The toothed belt is guided approximately horizontally next to the longitudinal cross-member 16 and extends around a toothed belt pulley assigned to the paddle wheel 27 of the device 10. This pulley is connected to a further spaced therefrom further pulley, which is associated with the third toothed belt. The third toothed belt finally drives a toothed belt pulley, which is fixed non-rotatably on one end of the shaft 29 of the impeller 27. This pulley is located on that end of the shaft 29, the fixed, axially non-displaceable disc 35 of the paddle wheel 27 is assigned. The toothed belt pulley is in this case on the outer side of the side bearing 30 directed away from the disk 35.

By the three toothed belt, the rotational movement of the pedals 19 is transmitted to the paddle wheel 27 of the device 10, which is thereby driven to rotate in the water. When belt drive of the training device shown here, the diameter of all pulleys are the same design, so that the rotational movement of the pedals 19 without translation or reduction, ie 1: 1, is transmitted to the paddle wheel 27. It is also conceivable, if necessary, to design the diameters of at least some toothed belt pulleys to be of different sizes so that the rotational movement of the pedals 19 is reduced or translated to the paddle wheel 27 of the device 10. At a ratio in the belt drive, the paddle wheel 27 moves faster than the pedals 19, whereby the device 10, a greater hydrodynamic resistance can be generated in the water. In such a case, it is conceivable to provide the blades 31 with smaller areas or to reduce the number of blades 31. The gear ratio may range from 1: 2 to 1: 6, preferably 1: 3 to 1: 5.

The Fig. 5 to 8 show a second embodiment of the exercise device according to the invention. This training device is different from the one of the Fig. 1 to 4 essentially only in that the device for generating a hydrodynamic resistance in the water is not arranged under the reclining seat 24, but approximately under the pedals 19 at the upper end of the front pillar 13. Incidentally, the training device of Fig. 4 to 8 trained as well as the training device of Fig. 1 to 4 , In that regard, the description of the training device of the Fig. 1 to 4 Referenced. Equal parts of the training device of Fig. 1 to 4 are in the Fig. 5 to 8 provided with the same reference number. In particular, the device with the width-adjustable paddle wheel 27 in the training device of Fig. 4 to 8 trained as well as the training device of Fig. 1 to 4 ,

In the following, only the differences of the exercise device of FIGS. 4 to 8 to the exercise device of FIGS. 1 to 4 of the first embodiment will be described:

In front of the front pillar 13, a lower obliquely oriented U-shaped bracket 48 and above a diagonally oriented traverse 49 are arranged. The oblique traverse 49 is connected on the one hand to the upper end of the column 13 and on the other hand to the upper end of the U-bracket 48.

In the U-bracket 48, namely between parallel obliquely upwardly extending legs 50 thereof, the paddle wheel 27 of the device 10 is supported, with opposite ends of the shaft 29 of the paddle wheel 27th

The shaft 29 is telescopically variable in length. For this purpose, the shaft 29 has a sleeve part 51 to which the fixed disc 35 is fixedly connected to the blade parts 33 attached thereto and designed as a solid shaft insertion part 52, the change in the length of the shaft 29 more or less in the sleeve part 51st is insertable. At the axially displaceable insertion part 52, the disc 34 and arranged on this adjustable blade parts 32 are attached.

In the vicinity of the free end of the rod-shaped insertion part 52, an adjusting lever 53 is arranged. With the adjustment lever 53, the exercising person can push the rod-like insertion part 52 into the sleeve part 51 of the shaft 29 and pull it out so as to change the width and thus the hydrodynamic resistance of the paddle wheel 27. In the embodiment shown, the insertion part 52 is associated with a fixed link 54. The gate 54 has several small distances to each other having cuts or depressions, in which the adjusting lever 53 or a guide pin attached thereto can engage. In this way, the stepwise set width of the paddle wheel 27 is locked. The locking is achieved by pivoting the adjusting lever 53 or the guide pin arranged thereon, so that they come out of the recess or the incision and along the link 54 are displaced to change the width of the paddle wheel 27th

The rotating drive in particular of the paddle wheel 27 of the device 10 takes place in the illustrated embodiment via a belt drive 55 between the shaft 29, namely the sleeve part 51, the paddle wheel 27 and the crank axle 21 of the pedals 19. The belt drive 25 may be a toothed belt drive, act a V-belt drive, a chain drive or the like. But there are also other power transmission means between the crank axle 21 of the pedals 19 and the shaft 29 of the paddle wheel 27 conceivable. The belt drive 55 is at least partially surrounded by a belt guard 56 in the embodiment shown. Likewise, an upper and rear portion of the periphery of the paddle wheel 27 facing the feet of the trained person is provided with a protective cover 57. The protective cover 57 and the belt guard 56 ensure that the person exercising with the feet does not accidentally get into moving parts of the belt drive 55 and the paddle wheel 27.

The pedals 19 may be provided with holding means, not shown in the figures, for the feet of the exercising person. The holding means may be loops, but also shoe caps or sandals of a waterproof material, such as plastic act.

The reclining seat 24 is the training device of Fig. 5 to 8 This can be done continuously, but also gradually, with a latching locking of the reclining seat 24 takes place on the connecting beams 18. In addition, 24 hand grips 58 are provided for holding the exercising person in the training device shown here on opposite sides of the reclining seat.

At the location of the reclining seat 24, the training device may also be provided with other seats. This applies to both embodiments of the training device described above.

Deviating from both embodiments described above, the paddle wheel 27 can also be driven directly, possibly also by the pedals 19th

The invention is suitable for all conventional training devices in which the force applied by the exercising person is transmitted to the device 10 according to the invention for generating a hydrodynamic resistance. The invention is particularly suitable for training devices that are not operated by the feet of a person exercising but alternatively or additionally of the hands, the buttocks, the legs, the arms or the like. Also, the exerciser need not be the recumbent bikes shown in the drawings. The training device can be designed as a seat bicycle, as a so-called crosstrainer, or as a rowing machine. Also, the training device may be provided with hand-operated pivoting levers.

LIST OF REFERENCE NUMBERS

10

contraption

11

frame

12

foot

13

pillar

14

pillar

15

crossbeam

16

Main beam

17

pillar

18

joining traverse

19

pedals

20

crank

21

crank axle

22

crank bearing

23

carriage

24

reclining seat

25

adjustment

27

paddle wheel

28

axis of rotation

29

wave

30

side bearing

31

shovel

32

blade part

33

blade part

34

disc

35

disc

36

groove

37

ring

40

poor

41

bell crank

42

swivel axis

43

quadrant

44

poor

45

handle

47

fixing bore

48

U-bolts

49

traverse

50

leg

51

sleeve part

52

insertion part

53

adjusting

54

scenery

55

belt drive

56

belt guard

57

protective cover

58

handle

Claims (15)

Device for generating a hydrodynamic resistance with preferably a plurality of blades (31) movable about a rotation axis (28), characterized in that the surfaces of the blades (31) are variable. Apparatus according to claim 1, characterized in that the surfaces of the blades (31), in particular of all blades (31) at the same time, during the movement of the blades (31) are variable, preferably continuously. Apparatus according to claim 1 or 2, characterized in that the blades (31) are arranged radially directed around the axis of rotation (38) around. Apparatus according to claim 1, characterized in that each blade (31) is formed in particular two preferably equally large blade parts (32, 33), wherein preferably the blade parts (32, 33) of the respective blade (31) overlap at least partially. Apparatus according to claim 4, characterized in that the surface of the respective blade (31) is variable by a change in the amount of overlap of the blade parts (32, 33). Apparatus according to claim 4 or 5, characterized in that the blade parts (32, 33) on two parallel, non-rotatably mounted on a about the rotational axis (28) rotatable shaft (29) mounted discs (34, 35), preferably each disc (34, 35) has a blade part (32, 33) of the respective blade (31). Apparatus according to claim 6, characterized in that at least one disc (34) with the blade parts (32) carried thereby is axially displaceable on the shaft (29) to change the spacing of the discs (34, 35) and to change the overlapping of the blade parts (32, 33) on the different discs (34, 35). Apparatus according to claim 6 or 7, characterized in that the blades (31) are arranged in a star shape around the shaft (29) around and are preferably completely submerged in water. Device according to one of claims 4 to 8, characterized in that the blades (31) and the blade parts (32, 33) are planar, preferably with rectangular bases. Device according to one of claims 6 to 9, characterized in that the shaft (29) is associated with a drive. Training device with pedals (19) which are mounted on a frame (11) and are preferably actuatable by feet and / or hands, and with blades (31) driven by the pedals (19) to produce a hydrodynamic resistance, characterized in that the surfaces of the blades ( 31) for changing their hydrodynamic resistance can be increased or reduced. Training device according to claim 11, characterized in that the blades (31) of the pedals (19) directly or at least one force transmission means are drivable. Training device according to claim 11 or 12, characterized in that the surfaces of the blades (31), preferably during their movement, by an adjusting device (25) are variable. Training device according to claim 13, characterized in that the adjusting device (25) can be actuated by hand, preferably continuously or virtually continuously. Training device according to one of claims 11 to 14, characterized by a device for changing the hydrodynamic resistance according to one or more of claims 1 to 10.

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