JP2011524235A - Training system with cycling equipment - Google Patents

Abstract

  A frame used to position the training system on the surface in use, a cycling device comprising at least one cycling member configured to pivot about a cycle axis, and moving at least one cycling member in a vibrating manner A training system for training a body part of a user, comprising the vibration device for the same, and the method and use.

Description

  The present invention relates to a training system (also called a training device) that trains a body part of a user. The training system includes a frame for positioning the training system on a surface when in use, and a cycling device (also referred to as a cycling means) including at least one cycling member configured to rotate around a cycle axis.

  In order to train the body part, the user performs a cycling exercise by rotating the cycling member around the cycle axis using the body part. The cycling member can include a pedal. The user can turn the pedal with his / her leg. The training system may include any other type of cycling device, such as a cycling device configured to rotate at least one cycling member with a portion of the user's body that is different from his / her leg. That will be clear. For example, the cycling member can be rotated about the cycling axis using the user's arm.

  A disadvantage of the training systems known from the prior art is that the user has to train for a relatively long time period in order for the user to achieve effective training.

  It is an object of the present invention to provide an improved training system.

  The training system according to the present invention includes a vibration device (also referred to as vibration means) that moves at least one cycling member in a vibration mode.

  In one embodiment of the training system according to the present invention, the vibration device is configured to move the cycle axis in a vibration mode. The training system can be configured such that, in use, the cycle axis moves in a vibrating manner relative to the frame. The cycling device can be connected to the frame such that the cycle axis is movable in a vibrating manner relative to the frame.

  In one embodiment of the training system of the present invention, the vibration device comprises a crankshaft connected to the cycle axis and configured to move the cycle axis in a vibrating manner. The crankshaft includes a crankshaft shaft, the cycle shaft can be disposed at a predetermined distance from the crankshaft shaft, and the crankshaft can be configured to rotate the cycle shaft about the crankshaft shaft. The crankshaft can be connected to the frame such that the crankshaft shaft is positioned at a substantially fixed position relative to the frame. The crankshaft can be composed of a first eccentric weight that compensates for the force induced by the oscillating motion of the cycle axis.

  The cycling device can be configured by a cycle disk configured to rotate around the cycle axis when at least one cycle member rotates around the cycle axis. The cycle disk can be engaged with an endless body. The vibration device may be configured to move the cycle disk in a vibration mode. The crankshaft can be composed of a second eccentric weight that compensates for the force induced by the oscillating motion of the cycle disk.

  In one embodiment of the training system according to the present invention, the cycle shaft is coupled to the cycle disk via a damping joint to reduce transmission of vibration motion of the cycle shaft to the cycle disk. The damping joint can be made of an elastic material that reduces the transmission of vibration motion of the cycle axis to the cycle disk. The damping joint can be composed of an elastic bushing that reduces the transmission of vibration motion of the cycle shaft to the cycle disk, and this elastic bush surrounds the cycle shaft. The damping joint can be composed of a rubber bush that reduces the transmission of the oscillating motion of the cycle shaft to the cycle disc, and this rubber bush surrounds the cycle shaft.

  The training system can be composed of a tension applying device that applies tension to an endless body with which the cycle disk is engaged. The tensioning device can be engaged with an endless body and connected to the crankshaft so that the tensioning device moves in reverse phase when in use when compared to the oscillatory motion of the cycle axis. The tensioning device can comprise at least one tensioning roller and a roller support that engages an endless body, the roller support connecting the at least one tensioning roller to a crankshaft, It moves in the opposite phase when in use when compared with the oscillating motion of the cycle axis.

  In one embodiment of the training system according to the present invention, the cycle disk engages the endless body in the first engagement region and the second engagement region, and the tension applying guide includes the first engagement region and the second engagement region. Engage the endless body with the engagement region. The first engagement region and the second engagement region can be arranged at a predetermined distance from each other.

  The training system can be configured by a drive device (also referred to as drive means) that drives the vibration device. The drive device can be configured to be driven by a cycling device. The training system can be composed of a coupling device that couples the drive device to the vibration device and separates the drive device from the vibration device. The connection device can be configured by a connection control member that controls connection and separation between the connection device and the vibration device.

  The frame can be composed of a seating member, and the cycle shaft can be movable in a vibrating manner relative to the seating member.

  In one embodiment of the training system according to the present invention, the cycling device can be swingably connected to the frame such that the cycle axis is movable relative to the frame in a vibrating manner.

  In a further embodiment of the training system according to the invention, the cycling device is connected to the frame via a rocking member. The rocking member can be configured with a longitudinal axis. The oscillating member can be constituted by an elongated main body formed of, for example, a beam-shaped part.

  The swing member can be swingably connected to the frame at a first connection point on the swing member. The vibration device can be connected to the swing member at a second connection point on the swing member. In the direction of the longitudinal axis, the first connection point and the second connection point can be arranged at a predetermined distance from each other.

  The cycling device can be connected to the rocking member at a third connection point of the rocking member. In the direction of the longitudinal axis, the third connection point can be arranged at a distance farther from the first connection point than the second connection point is located from the first connection point. In the direction of the longitudinal axis, the second connection point can be arranged at a distance farther from the first connection point than the third connection point is located from the first connection point. In the direction of the longitudinal axis, the second connection point can be arranged from the first connection point at the same distance as the third connection point is located from the first connection point.

  The damper (also referred to as damping means) can be connected to the swing member at a fourth connection point on the swing member. In the direction of the longitudinal axis, the third connection point can be arranged at a distance farther from the first connection point than the fourth connection point is located from the first connection point. In the direction of the longitudinal axis, the fourth connection point can be arranged at a distance farther from the first connection point than the third connection point is located from the first connection point. In the direction of the longitudinal axis, the third connection point can be arranged from the first connection point at the same distance as the fourth connection point is located from the first connection point.

  The swing member can be formed of a swing portion that extends from one side of the frame. The first connection point can be disposed on the swinging portion. The second connection point can be disposed on the rocking part. The third connection point can be arranged on the rocking part. The fourth connection point can be arranged on the rocking part.

  In one embodiment of the training system according to the present invention, the vibration device comprises a crankshaft connected to a swing member. The crankshaft can be connected to the swing member at the second connection point. The crankshaft can be connected to the swing member via a connecting rod. It will be apparent that the crankshaft can be connected to the rocking member via any other kind of connecting rod.

  The training system can be composed of a drive device that drives the crankshaft. The driving device may be an electric motor connected to a crankshaft. The vibration device can be driven by a cycling device. The crankshaft can be driven by a cycling device. The driving device may be a flywheel connected to a crankshaft. The flywheel can be coupled to the crankshaft such that the rotational movement of the flywheel is transmitted to the crankshaft. The flywheel can be connected to the crankshaft by an endless drive. The endless driving body may be any appropriate type of endless body such as an endless belt or an endless chain. The flywheel can be connected to the crankshaft by at least one endless drive. The flywheel can be connected to the crankshaft by a single endless drive. The flywheel can be connected to the crankshaft via a gear device (also referred to as gear means). The gear device is configured to select different gear ratios. The gear device can be constituted by a derailleur gear or a hub gear. The flywheel can be driven by a cycling device. The cycling device can be coupled to and drive the flywheel. The flywheel can be coupled to the cycling device such that the rotational movement of at least one cycle member is transmitted to the flywheel. The cycling device can be connected to the flywheel by an endless circulator. The endless circulator may be any appropriate type of endless body such as an endless belt or an endless chain. The cycling device can be connected to the flywheel by at least one endless circulator. The cycling device can be connected to the flywheel by a single endless circulator. The flywheel can be formed of a first connecting member that engages with the endless drive body. A flywheel can be comprised by the 2nd connection member engaged with an endless circulation body. The cycling device can be connected to the flywheel via a gear device. The cycling device can be constituted by a third connecting member that engages with the endless circulator. The cycling device can be constituted by a cycle disk configured to rotate around the cycle axis when at least one cycle member is rotated around the cycle axis. The cycle disk can be composed of a third connecting member. The vibration device can be constituted by a fourth connecting member that engages with the endless circulator. The crankshaft can be composed of a fourth connecting member.

  In a further embodiment of the training system according to the invention, the vibration device comprises at least one eccentric weight pivotably connected to the rocking member and at least one such that the rocking member moves in a rocking manner. And an electric drive machine for rotating the eccentric weight.

  In another embodiment of the training system according to the present invention, the vibration device comprises a disk-shaped member connected to the cycling device so that the disk-shaped member can be rotated about the cycle axis. Protrusions extending substantially in the radial direction are provided around the disk-shaped member. The vibration device further includes a pressing device (also referred to as a pressing unit) that presses against the peripheral edge so that at least one cycling member moves in a vibration mode when the disk forming member is rotated around the cycle axis. . The protrusion on the periphery of the disk-shaped member can be formed by the periphery having a shape such as a curved shape or a polygon. The central axis of the disk-shaped member can extend substantially parallel to the cycle axis. The central axis of the disk-shaped member can be substantially aligned with the cycle axis.

  The pressing device is configured to press the pressing member against the periphery of the disk-shaped member. The pressing member can be pressed against the peripheral edge by a spring. The pressing device can be configured such that the pressing member can be displaced only in the radial direction with respect to the cycle axis.

  In one embodiment of the training system of the present invention, the cycling device drives the endless body, and the vibration device is configured to vibrate the endless body so that at least one cycling member moves in a vibrating manner. The endless body can be a drive chain, a drive belt, or the like. The vibration device can be configured to drive the impact member in an oscillation manner with respect to the endless body. The vibration device can be configured to drive the impact member in an oscillating manner on both sides of the endless body. The vibration device can be composed of a solenoid that drives the impact member in an oscillation manner.

  In a further embodiment of the training system of the present invention, the training system comprises an adjustable cycling resistor that provides resistance to and adjusts the rotation of the cycling member about the cycle axis.

  In another embodiment of the training system according to the present invention, the cycle axis is fixed to the frame. In said embodiment, the oscillating motion of at least one cycling member is transmitted to the frame.

  The present invention further relates to a method for training a user's body part, wherein the body part is used to rotate at least one cycle member about a cycle axis of a training system according to the present invention.

  The invention further relates to the use of the training system according to the invention.

  The training system according to the present invention and the method and use of the training system will be described in detail with reference to the accompanying drawings.

1 schematically shows a side perspective view of a first embodiment of a training system according to the present invention. FIG. FIG. 2 schematically shows an enlarged view of a portion II in FIG. 1. Fig. 3 schematically shows a side perspective view of a second embodiment of a training system according to the present invention. Fig. 6 schematically shows a side perspective view of a third embodiment of a training system according to the present invention. Fig. 6 schematically shows a side perspective view of a fourth embodiment of a training system according to the present invention. Fig. 6 schematically shows a side view of a fifth embodiment of a training system according to the present invention. FIG. 9 schematically shows a side view of a sixth embodiment of a training system according to the present invention. FIG. 9 schematically shows a side view of a seventh embodiment of a training system according to the invention. FIG. 9 schematically shows an enlarged view of a portion IX in FIG. 8, and reference numerals corresponding to those in FIGS. 1 to 9 relate to corresponding features. A perspective view of an 8th embodiment of a training system concerning the present invention is shown roughly. FIG. 11 schematically shows a side view of the training system of FIG. 10 in the direction of arrow XI. FIG. 11 schematically shows a side view of the training system of FIG. 10 in the direction of arrow XII. Fig. 13 schematically shows a cross-sectional perspective view of the training system of Fig. 12 along line XIII. FIG. 13 schematically shows a cross-sectional perspective view of the training system of FIG. 12 along line XIV. Fig. 3 schematically shows a side view of an alternative embodiment of a cycling device and a vibration device of a training system according to the present invention. Fig. 3 schematically shows a side view of an alternative embodiment of a cycling device and a vibration device of a training system according to the present invention. Fig. 3 schematically shows a side view of an alternative embodiment of a cycling device and a vibration device of a training system according to the present invention. Fig. 3 schematically shows a side view of an alternative embodiment of a cycling device and a vibration device of a training system according to the present invention. Fig. 3 schematically shows a side view of an alternative embodiment of a cycling device and a vibration device of a training system according to the present invention. 9 schematically shows a ninth embodiment of the training system according to the present invention. 9 schematically shows a ninth embodiment of the training system according to the present invention. 9 schematically shows a ninth embodiment of the training system according to the present invention. 9 schematically shows a ninth embodiment of the training system according to the present invention. 9 schematically shows a ninth embodiment of the training system according to the present invention. 9 schematically shows a ninth embodiment of the training system according to the present invention. 9 schematically shows a ninth embodiment of the training system according to the present invention. 10 schematically shows a tenth embodiment of a training system according to the present invention. 10 schematically shows a tenth embodiment of a training system according to the present invention. 11 schematically shows an eleventh embodiment of a training system according to the present invention. 11 schematically shows an eleventh embodiment of a training system according to the present invention. 12 schematically shows a twelfth embodiment of a training system according to the present invention. 12 schematically shows a twelfth embodiment of a training system according to the present invention. 12 schematically shows a twelfth embodiment of a training system according to the present invention. 13 schematically shows a thirteenth embodiment of the training system according to the present invention. 13 schematically shows a thirteenth embodiment of the training system according to the present invention. 14 schematically shows a fourteenth embodiment of a training system according to the present invention. 14 schematically shows a fourteenth embodiment of a training system according to the present invention. 15 schematically shows a fifteenth embodiment of the training system according to the present invention. 16 schematically shows a sixteenth embodiment of the training system according to the present invention. 16 schematically shows a sixteenth embodiment of the training system according to the present invention. 16 schematically shows a sixteenth embodiment of the training system according to the present invention.

  1 to 40, corresponding features are indicated by corresponding reference numerals.

  FIG. 1 shows a training system 1 for training a body part of a user. The training system 1 is composed of a frame 2 used to position the training system 1 on a surface 3 and a cycling device 4 comprising two cycling members 5. The cycling member 5 is configured to rotate about the cycle axis 6. The vibration device 7 is arranged to move the cycling member 5 in a vibrating manner.

  The cycling member 5 is a pedal, and a user's foot is placed on the pedal when in use. To train the user's lower body, he / she rotates his / her legs and feet by rotating the cycling member 5 about the cycle axis 6. During the cycling movement, the vibration movement of the cycling member is transmitted to the lower body of the user's body. The vibration motion of the cycling member 5 is added to the rotational motion of the cycling member 6 around the cycle axis 6. Thereby, more efficient training is obtained. The same training effect is achieved in a shorter period of time when compared with training systems known from the prior art.

  The frame 2 of the training system 1 includes a seating member 8 and a user support 34. The swing member 9 is swingably connected to the frame 2 at a first connection point 11 of the swing member 9. The vibration device 7 is connected to the swing member 9 at a second connection point 12 on the swing member 9. The swing member 9 includes a longitudinal axis 10. In the direction of the longitudinal axis 10, the first connection point 11 and the second connection point 12 are arranged at a predetermined distance from each other.

  The cycling device 4 is connected to the swing member 9 at a third connection point 13 of the swing member 9. In the direction of the longitudinal axis 10, the third connection point 13 is arranged from the first connection point 11 at a distance farther from the first connection point 11 than the second connection point 12 is located. The swing member 9 includes a swing portion 16 extending from one side 35 of the frame 2. The first connection point 11, the second connection point 12, and the third connection point 13 are located on the swing part 16.

  The vibration device 7 includes a crankshaft 17 connected to the swing member 9 at the second connection point 12 via a connecting rod 36. The crankshaft 17 provides a reliable structure that provides an oscillating movement of the cycling device 4 connected to the rocking member 9. Furthermore, the crankshaft 17 is relatively quiet when in use.

  The training system 1 includes a drive device 18 that drives the crankshaft 17. The drive device 18 includes a flywheel 20 that is rotatable around a flywheel shaft 37. The flywheel 20 is mechanically coupled to the crankshaft 17 so that the rotational movement of the flywheel 20 is transmitted to the crankshaft 17. The flywheel 20 is also mechanically connected to the cycling device 4 so that the rotational movement of the cycling member 5 about the cycling axis 6 is transmitted to the flywheel 20. This means that the crankshaft 17 is driven by the cycling device 4. The oscillating movement of the cycling member 5 is therefore driven by the rotation of the cycling member 5 about the cycle axis 6. The vibration device 7 is driven by a user that rotates the cycling member 5 around the cycle axis 6 in use. The flywheel 20 is connected to the crankshaft 17 by two endless bodies 38 (hereinafter each referred to as an endless drive body 38) and to the cycling device 4 by one endless body 39 (hereinafter referred to as an endless circulation body 39). It is mechanically linked. The cycling device 4 includes a cycle disk 30 configured to rotate about the cycle axis 6 when the cycle member 5 is rotated about the cycle axis 6. The flywheel 20 includes a first connection member 51 that engages with one endless drive body 38 and a second connection member (not shown) that engages with the endless circulation body 39. The cycle disk 30 includes a third engagement member 53 that engages with the endless circulator 39. The crankshaft 17 includes a fourth connecting member 54 that engages with the other endless drive body 38.

  Due to the fact that the swinging member 9 is swingably connected to the frame 2, the cycling device 4 performs a vibrating motion relative to the frame 2 in use. Thus, the oscillating movement of the cycling device 4 relative to the frame 2 is achieved with a simple and effective construction. The swing member 9 is formed from a beam-shaped part. In the training system 1, the cycle shaft 6 performs a vibrating motion with respect to the frame 2 when in use. This provides an effective way to move the cycling member 5 in a vibrating manner. In addition, this ensures that the vibrations of the cycle shaft 6 are not transmitted to the frame 2 (or at least in a significantly reduced form). Thereby, a more effective vibration of the cycling member 5 is obtained, because the vibration of the cycling device 4 is not damped by the frame 2. In addition to this, a more comfortable workout is provided, since the user supported on the frame via the seating member 8 and the user support 34 is not exposed to the vibrating movement of the seating member 8 and / or the user support 34. (Or at least significantly reduced form). If necessary, transmission of the vibration motion of the cycling device 4 to the frame 2 can be further reduced using a damper (not shown). The training system 1 further comprises a base plate 41 connected to the vibration device 7. The base plate 41 has a relatively large mass and provides stability to the training system 1.

  FIG. 2 shows an enlarged view of part II of FIG. The oscillating movement of the oscillating member 9 and the cycle shaft 6 provided by the crankshaft 17 is indicated by arrows 40.

  FIG. 3 shows a second embodiment of the training system 1 according to the present invention. In the training system 1, the flywheel 20 is connected to the crankshaft 17 via the gear device 21. The gear device 21 is configured to select different gear ratios. The gear ratio can be adjusted by a gear controller 42 located on the user support 34. The gear device 21 includes a hub gear. By selecting different gear ratios, the resistance to rotation of the cycling member 5 about the cycle axis 6 is adjusted.

  FIG. 4 shows a third embodiment of the training system according to the present invention. In the training system 1, the drive device 18 includes an electric motor 19 mechanically connected to the crankshaft 17. The electric motor 19 is mechanically connected to the crankshaft 17 by a drive belt 38. The flywheel 20 is mechanically connected to the cycling device 4 by a drive chain 39. In the training system 1, the flywheel 20 is not mechanically connected to the crankshaft 17. The vibration device 7 is driven by an electric motor 19. The flywheel 20 may be mechanically connected to the crankshaft 17. In this case, the vibration device 7 (more specifically, the crankshaft 17) is driven by the electric motor 19 and / or the cycling device 4.

  FIG. 5 shows a fourth embodiment of the training system according to the present invention. In the direction of the longitudinal axis 10, the second connection point 12 is arranged from the first connection point 11 at a distance farther from the first connection point 11 than the third connection point 13 is located. The damper 15 is connected to the swing member 9 at a fourth connection point 14 on the swing member 9. The damper 15 is supported by a damping support body 46. The damper 15 provides additional stability against the oscillating movement of the rocking member 9. In the direction of the longitudinal axis 10, the third connection point 13 is arranged from the first connection point 11 at a distance farther from the first connection point 11 than the fourth connection point 14 is located.

  The vibration device 7 includes an eccentric weight that is pivotally connected to the swing member 9 and an electric drive machine that rotates the eccentric weight. The eccentric weight and the electric drive machine together form the vibration motor 22. By rotating at least one eccentric weight, vibration motion of the eccentric weight is generated. The eccentric weight is connected to the swing member 9 so that the vibration motion is transmitted to the swing member 9. Thereby, the cycling device 4 moves in a vibration mode. The oscillating motion is indicated by arrow 40.

  The vibration motor 22 is controlled by the control unit 44. The user can adjust the vibration movement of the cycling device 4 using the control panel 43 in communication with the control unit 44.

  FIG. 6 shows a fifth embodiment of the training system according to the present invention. The vibration device 7 includes a disk-shaped member 24, which is connected to the cycling device 4 so that the disk-shaped member 24 can rotate around the cycle axis 6. A peripheral edge 25 of the disk-shaped member 24 includes a protrusion 26 extending in a substantially radial direction. The vibration device 7 further includes a pressing device 27 that presses against the peripheral edge 25 so that vibration is generated when the disk-shaped member 24 rotates around the cycle axis 6. The protrusions 26 on the peripheral edge 25 of the disk-shaped member 24 are formed by the curved shape of the peripheral edge 25. The disc-shaped central axis 24 coincides with the cycle axis 6.

  The pressing device 27 is configured to press the pressing member 28 against the peripheral edge 25 of the disk-shaped member 24. The pressing member 28 is pressed against the peripheral edge by the spring 45. The pressing device 27 is configured such that the pressing member 28 can be displaced only in the radial direction with respect to the cycle shaft 6.

  The cycle shaft 6 is fixed to the frame 2. Therefore, the vibration motion of the cycling member 5 is transmitted to the frame 2.

  The training system 1 further includes an adjustable cycling resistor 33 that provides resistance to and adjusts the rotation of the cycling member 5 about the cycle axis 6. By adjusting the resistance against the rotation of the cycling member 5 around the cycle axis, the magnitude of the resistance is adjusted. The cycling resistor 33 and the cycling device 4 are mechanically connected to the drive chain 39.

  FIG. 7 shows a sixth embodiment of the training system according to the present invention. The training system 1 includes a swing member 9 that is swingably connected to the frame 2. A pressing device 27 is fixed to the frame 2. The pressing member 28 of the pressing device 27 is forcibly brought into contact with the peripheral edge 25 of the disk-shaped member 24 by a spring 29 acting on the swing member 9. In the direction of the longitudinal axis 10, the second connection point 12 and the third connection point 13 are located at the same distance from the first connection point 11.

  FIG. 8 shows a seventh embodiment of the training system according to the present invention. The cycling device 4 drives an endless body (drive chain 39), and the vibration device 7 is configured to vibrate the vibration chain 39. The endless body can be a drive belt or the like. The vibration device 7 is configured to drive the impact member 32 with respect to the drive chain 39 in an oscillation manner. The vibration device 7 is configured to drive the impact member 32 in an oscillating manner on both sides of the drive chain 39. The oscillation motion of the impact member 32 is indicated by an arrow 45. The vibration device 7 includes a solenoid 31 that drives the impact member 32 in an oscillation manner. The impact of the impact member 32 on the drive chain 39 ensures that the cycling member 5 moves in a vibrating manner.

  FIG. 9 is an enlarged view of a portion IX in FIG.

  10 to 14 show an eighth embodiment of the training system of the present invention. The vibration device 7 includes a crankshaft 17 connected to the swing member 9. The crankshaft 17 is connected to the swing member 17 at the second connection point 12. The crankshaft 17 is connected to the frame 2 by a connecting rod 36 that can swing.

  The vibration device 7 is driven by the cycling device 4. The cycling device 4 includes a cycle disk 30 configured to rotate about the cycle axis 6 when the cycle member 5 is rotated about the cycle axis 6. The cycling device 4 is mechanically coupled to the flywheel 20 so that the rotational movement of the cycle member 5 is transmitted to the flywheel 20. The cycle disk 30 includes a third connecting member 53 that engages with the endless circulator 39. The flywheel 20 includes a second connecting member 52 that engages with the endless circulator 39. This means that the cycling device 4 and the flywheel 20 are mechanically connected to each other with only one endless circulation body 39. The endless drive 39 can be any suitable type of endless, such as an endless belt or an endless chain. The endless circulator 39 is guided by a first guide device (also referred to as first guide means) 47. The first guide device 47 includes a pair of roller guides.

  The flywheel 20 is mechanically connected to the crankshaft 17 so that the rotational movement of the flywheel 20 is transmitted to the crankshaft 17. The flywheel 20 is mechanically connected to the crankshaft 17 by an endless drive body 38. The flywheel 20 includes a first connecting member 51 that engages with the endless drive body 38. The crankshaft 17 includes a fourth connecting member 54 that engages with the endless drive body 38. This means that the flywheel 20 and the crankshaft 17 are mechanically connected to each other with only one endless drive 38. The endless driver 38 may be any suitable type of endless body such as an endless belt or an endless chain. The endless circulator 39 is guided by a second guide device (also referred to as second guide means) 48. The first guide device 48 includes a pair of roller guides.

  The connection of the flywheel 20 and / or the cycle disc 30 and / or the crankshaft 17 also includes the flywheel axis 37 of the flywheel and / or the cycle axis 6 of the cycling device 4 and / or the axis of the crankshaft. However, it will be apparent that the pivoting motion is transmitted between the flywheel 20 and / or the cycle disk 30 and / or the crankshaft 17, respectively. In this case, the first connecting member 51 and / or the second connecting member 52 can be disposed on the flywheel shaft 37 at a predetermined distance from the flywheel 20, and / or the third connecting member 53 is The cycle disk 30 may be disposed on the cycle shaft 6 at a predetermined distance, and / or the fourth connecting member 54 may be disposed on the axis of the crankshaft 17 at a predetermined distance from the crankshaft 17. .

  FIG. 15 shows a side view of a first alternative embodiment of the cycling device and a side view of the oscillation device of the training system according to the present invention. The cycling device 4 includes two cycling members 5 that can rotate around the cycle axis 6. Each cycling member 5 includes a cycling rod 56 and an engaging member 50 connected thereto, and the engaging member 50 is rotatably mounted around a member shaft 49. The engaging member 50 is connected to the cycling rod 56 via the vibration device 7. The engaging member 50 is connected to the cycling rod 56 via the crankshaft 17. A cycle disk 30 that can rotate around the cycling axis 6 is provided. The cycling device 4 is connected to the cycle disk 30 so that the cycle disk 30 rotates when the cycling device 4 is rotated about the cycle axis 6. The cycle disk 30 is connected to the vibration device 7 by the endless driver 38 and thus to the crankshaft 17 of each cycling member 5. When the cycling member 5 is rotated about the cycle axis 6, the cycle disk 30 drives the crankshaft 17 of each cycling member 5 via the endless drive body 38. The drive of the crankshaft 17 causes the engagement member 50 to vibrate as indicated by the arrow 40. It will be apparent that any suitable vibration device 7 other than the crankshaft 17 can be used. The cycle disk 30 can also be connected to a cycling resistor 33.

  16 and 17 show side views of side views of second and third alternative embodiments of the cycling device and vibration device of the training system according to the present invention, respectively. In these embodiments, the cycle disk 30 is configured such that the cycle disk 30 directly contacts the vibration device 7 in order to drive the vibration device 7. The cycle disk 30 is fixed to the cycling shaft 6. This means that the cycle disc 30 does not rotate about the cycling axis 6 when the cycling member 5 rotates about the cycling axis 6. The cycle disc 30 can be configured such that the cycle disc 30 does not substantially rotate about the cycling axis 6 when the cycling member 5 rotates about the cycling axis 6. The crankshaft 17 is in contact with the disk peripheral edge 55 of the cycle disk 30. In the embodiment of FIG. 16, the crankshaft 17 is in contact with the outer surface 58 of the disk peripheral edge 55. In the embodiment of FIG. 17, the crankshaft 17 is in contact with the inner surface 58 of the disk peripheral edge 55. By rotating the cycling member 5 with respect to the cycle disk 30, the crankshaft 17 is driven so that the engaging member 50 vibrates as indicated by an arrow 40.

  FIG. 18 shows a side view of a fourth alternative embodiment of the cycling device and the vibration device of the training system according to the present invention. The cycling device 4 is configured such that the cycling device 4 can rotate around the cycling axis 6 via a crankshaft 17. This causes the rotation of the cycling member 5 around the cycling axis 6 to cause the vibration of the cycling member 5 indicated by the arrow 40. The cycling device 4 can be coupled to the flywheel 20 so that the flywheel 20 rotates about the cycling axis 6 when the cycling member 5 is rotated about the cycle axis 6.

  FIG. 19 shows a side view of the fifth alternative embodiment of the cycling device and the vibration device of the training system according to the present invention. The cycling device 4 includes a cycle disk 30 connected to the flywheel 20 by an endless circulator 39. The flywheel 20 is rotatable around the flywheel shaft 37. The flywheel 20 is connected to the cycling device 4 by the swing member 9. The swing member 9 can swing around the pivot shaft 57. The pivot shaft 57 is fixed to the cycling device 4. The swing member 9 is connected to the cycling device 4 at its first end 61 and is connected to the flywheel 20 at its second end 62. The pivot shaft 57 is located between the first end portion 61 and the second end portion 62 of the swing member 9. The swing member 9 is connected to the flywheel 20 at an eccentric connection point 60. The eccentric connection point 60 is slidably connected to the swing member 9. The eccentric connection point 60 is slidable through an opening 61 disposed in the swing member 9. The rotation of the flywheel 20 causes the second end 62 of the swing member 9 to vibrate as indicated by the arrow 63. By the pivot shaft 57, the movement of the second end 62 is transmitted to the first end 61 of the swinging member 9 so that the first end 61 vibrates as indicated by the arrow 40. Thereby, the cycling member 5 vibrates.

  20 to 25 show a ninth embodiment of the training system according to the present invention. Reference numerals 8 and 34 indicate locations where the seating member and the user support (not shown) are positioned during use, respectively. In use, a cycling member (not shown) is connected to the cycling shaft 6. The cycle disk 30 is configured to rotate about the cycle axis 6 when two cycle members rotate about the cycle axis 6. The cycle disk 30 is connected to the flywheel 20 by an endless body, more specifically, an endless circulation body 39.

  The driving device 18 is connected to the vibration device 7 by an endless driving body 38. The vibration device 7 includes a crankshaft 17. The crankshaft 17 is connected to the cycle shaft 6 and is configured to move the cycle shaft 6 in a vibration mode 40. The crankshaft 17 includes a crankshaft shaft 63 around which the crankshaft 17 rotates. The cycle shaft 6 is located at a predetermined distance from the crankshaft shaft 63. The crankshaft 17 is configured to rotate the cycle shaft 6 around the crankshaft shaft 63 as indicated by an arrow 40 in FIG. The vibration motion 40 of the cycle axis 6 can be divided into a horizontal motion Ah and a vertical motion Av. The crankshaft 17 is connected to the frame 2 by a bearing 78. In use, the crankshaft shaft 63 is located at a fixed position with respect to the frame 2.

  The cycle axis 6 is directly connected to the cycle disk 30 so that the cycle disk 30 vibrates along the cycle axis 6 when the cycle axis 6 moves in the vibration mode 40. The crankshaft 17 includes a first eccentric weight and a second eccentric weight (see 97 in FIG. 25) that compensate for the force induced by the vibration motion of the cycle axis and the cycle disk 30, respectively. The first eccentric weight and the second eccentric weight are integrated with each other to form one eccentric weight 97. FIG. 25 shows a cross-sectional view along the line shown in FIG.

  The training system 1 includes a tension applying device 68 that applies tension to the endless circulator 39 when the cycle disk 30 moves in a vibrating manner. The tension applying device 68 is engaged with the endless circulator 39 by the first tension applying roller 69 and the second tension applying roller 70. The first tension applying roller 69 and the second tension applying roller 70 can be rotated around the rotation shafts 76 and 77. The first tension applying roller 69 and the second tension applying roller 70 are connected to the crankshaft 17 via a roller support 72. The roller support 72 is swingably connected to the crankshaft 17 so that the tension applying device 68 moves in a reverse phase when in use when compared with the vibration motion 40 of the cycle shaft 6. This means that when the cycle shaft 6 moves in a predetermined direction, the tension applying device moves in the opposite direction. The tensioning movement of the tensioning device 68 is indicated by an arrow 71. The tension applying motion 71 is such that when the first tension applying roller 69 and the second tension applying roller 70 are engaged with the endless circulation belt 39 and thus the cycle disk 30 is moved by the vibration cycle shaft 6, the endless circulation belt 39 is moved. Ensure that tension is maintained.

  The training system 1 includes a connecting device 64 that connects the driving device 18 to the vibration device 7 and separates the driving device 18 from the vibration device 7. The connection device 64 includes a connection control member 75 that controls connection and separation between the connection device 64 and the vibration device 7. The coupling device 64 includes a coupling roller 65 that is movable between a coupling position 66 and a non-coupling position 67. The connection roller 65 is mounted on the connection bar 73 and can be rotated around the rotation shaft 74. The connection bar 73 is movable by means for connecting the control member 75 so that the connection roller 65 can be positioned at the connection position 66 and the separation position 67. At the coupling position 66, the coupling roller 65 engages with the flywheel 20 so that the rotation of the flywheel 20 is transmitted to the coupling roller 65 (see FIGS. 20 and 21). Thus, the driving device 18 is driven by the cycling device 4. In the non-connection position 67, the connection roller 65 does not engage with the flywheel 20, so that the rotation of the flywheel 20 is not transmitted to the connection roller 65 (see FIGS. 22 and 23).

  FIG. 24B shows a modified example of the training system of FIGS. 20 to 23, FIG. 24A, and FIG. The gear device 21 is connected to the driving device 18, more specifically, to the endless driving belt 38 via a connecting shaft 74 of the connecting roller 65. The gear device 26 is in communication connection with the gear controller 42 (see FIG. 20) via the communication member 99. The gear device 21 is configured to provide different gear ratios. The gear ratio can be adjusted by the gear controller 42. The gear device 21 includes a hub gear. The drive of the vibration device 7 is controlled by controlling the gear ratio. This means that the gear device 21 allows the user to control the frequency at which the vibration device 7 moves the cycle shaft 6 in a vibration mode.

  26 and 27 show a tenth embodiment of a training system according to the present invention.

  28 and 29 show an eleventh embodiment of the training system according to the present invention. The cycle disk 30 engages with the endless circulator 39 in the first engagement region 95 and the second engagement region 96. The tension applying guide 79 is engaged with the endless circulator 39 between the first engagement region 95 and the second engagement region 96. The first engagement region 95 and the second engagement region 96 are located at a predetermined distance from each other. As a result, when the cycle disk 30 moves due to the oscillating motion of the cycle shaft 6, the endless circulation belt 39 can be kept in a tensioned state. The tension application guide 79 includes a tension application roller 80.

  30 to 32 show a twelfth embodiment of the training system according to the present invention. The cycle shaft 6 is connected to the cycle disk 30 via a damping joint 81 to reduce transmission of the vibration motion 40 of the cycle shaft 6 to the cycle disk 30. The damping joint 81 includes an elastic material that reduces transmission of the vibration motion 40 of the cycle shaft 6 to the cycle disk 30. The damping joint 81 includes a rubber bush that surrounds the cycle shaft 6. 31 shows a cross-sectional view along the line shown in FIG.

  33 to 34 show a thirteenth embodiment of the training system according to the present invention. The cycling device 4 is connected to the first wheel 82 via an endless cycling belt 39. The connecting device 64 is connected to the first wheel 82 and drives the vibration device 7. The training system 1 further comprises a second wheel 83 that can be steered by the user support 34.

  35 and 36 show a fourteenth embodiment of the training system according to the present invention. The drive device includes an endless drive belt 38 that directly connects the vibration device 7 to the first wheel 82.

  FIG. 37 shows a fifteenth embodiment of the training system according to the present invention. The foot support 85 is pivotably connected to the cycling member 5 (around the pivot shaft 87) at one end thereof. At the other end, the foot support 85 is pivotally connected to the hand rod 84 (around the pivot axis 88). The hand rod 84 is swingably connected to the frame 2 (around the pivot shaft 86). In use, the foot support 85 performs an elliptical motion.

  38 to 40 show a sixteenth embodiment of the training system according to the present invention. The cycle shaft 6 is connected to a connection member 89. The connecting member 89 is disposed in the member guide 90. The member guide 90 guides the connecting member 89 so that the connecting member 89 is movable along a substantially straight line. The connection member 89 is locked to the damper 15. The cycle shaft 6 is connected to the vibration device 7 via a connection member 89. The vibration device 7 includes an eccentric weight 92 that can rotate around an eccentric weight shaft 93. The vibration device 7 includes a connecting member 91 that can rotate around the eccentric weight shaft 93 and is connected to the cycle disk 30 by an endless body 94 to drive the vibration device 7. When the cycling member 5 is rotated about the cycle axis 6, the cycle disk 30 drives the vibration device 7, the eccentric weight 92 rotates about the eccentric weight shaft 93, and the connection member 89 is thus similarly configured to the cycle axis. 6 vibration motions 40 are generated. The cycle shaft 6 vibrates along a substantially straight line by the member guide 90. FIG. 40 shows an exploded view of the training system 1.

  This application can be defined by one or any combination of the following clauses.

1. A frame to position the training system on the surface when in use;
A cycling device comprising at least one cycling member configured to pivot about a cycle axis;
A training system for training a user's body part, comprising: a vibration device that moves at least one cycling member in a vibrating manner.

  2. The training system according to clause 1, wherein the vibration device is configured to move the cycle axis in a vibration mode.

  3. The training system according to any of the preceding clauses, wherein the cycle axis is configured to move in a vibrating manner relative to the frame when in use.

  4). The training system according to any of the preceding clauses, wherein the cycling device is connected to the frame such that the cycle axis is movable in a vibrating manner relative to the frame.

5. The training system according to any of the preceding clauses, wherein the vibration device comprises a crankshaft connected to the cycle axis and configured to move the cycle axis in a vibrating manner.

  6). The training system according to clause 5, wherein the crankshaft includes a crankshaft shaft, the cycle shaft is located at a predetermined distance from the crankshaft shaft, and the crankshaft is configured to rotate the cycle shaft about the crankshaft shaft.

  7). The training system according to any one of clauses 5 and 6, wherein the crankshaft is connected to the frame so that the crankshaft shaft is located at a substantially fixed position with respect to the frame.

  8). The training system according to any of clauses 5 to 7, wherein the crankshaft comprises a first eccentric weight that compensates for the force induced by the vibration motion of the cycle axis.

  9. The training system according to any of the preceding clauses, wherein the cycling device includes a cycle disk configured to rotate around the cycle axis when at least one cycle member is rotated about the cycle axis.

  10. The training system of clause 9, wherein the cycle disk engages the endless body.

  11. The training system according to any one of clauses 9 and 10, wherein the vibration device is configured to move the cycle disk in a vibration mode.

  12 12. The training system of clause 11 in combination with any of clauses 5 to 8, wherein the crankshaft comprises a second eccentric weight that compensates for the force induced by the oscillating motion of the cycle disk.

  13. 11. The training system according to any of clauses 9 or 10, wherein the cycle shaft is connected to the cycle disk via a damping joint to reduce transmission of vibration motion of the cycle shaft to the cycle disk.

  14 The training system of clause 13, wherein the damping joint comprises an elastic material that reduces transmission of vibration motion of the cycle axis to the cycle disk.

  15. 15. A training system according to any of clauses 13 or 14, wherein the damping joint comprises an elastic bushing that reduces the transmission of the oscillating motion of the cycle axis to the cycle disk, the elastic bushing surrounding the cycle axis.

  16. The training system according to any one of clauses 13 to 15, wherein the damping joint includes a rubber bushing that reduces transmission of vibration motion of the cycle shaft to the cycle disk, and the rubber bush surrounds the cycle shaft.

  17. The training system according to any of clauses 10 to 16, further comprising a tension applying device that applies tension to an endless body with which the cycle disk is engaged.

  18. 18. The training system according to clause 17, wherein the tensioning device is engaged with an endless body and connected to the crankshaft so that the tensioning device moves in reverse phase when in use when compared with the oscillating motion of the cycle axis.

  19. The tensioning device comprises at least one tensioning roller that engages an endless body and a roller support, the roller support connecting the at least one tensioning roller to the crankshaft, and the cycle axis oscillatory motion The training system according to any one of clauses 17 and 18, which moves in reverse phase when in use when compared with.

  20. The cycle disc is engaged with the endless body in the first engagement area and the second engagement area, and the tension applying guide is engaged with the endless body between the first engagement area and the second engagement area. The training system according to any one of clauses 10 to 19.

  21. The training system according to clause 20, wherein the first engagement region and the second engagement region are arranged at a predetermined distance from each other.

  22. The training system according to any of the preceding clauses, comprising a drive device that drives the vibration device.

  23. The training system according to clause 22, wherein the driving device is driven by a cycling device.

  24. 24. A training system according to any of clauses 22 or 23, comprising a coupling device for coupling the drive device to the vibration device and separating the drive device from the vibration device.

  25. The training system according to clause 24, wherein the coupling device includes a coupling control member that controls coupling and separation between the coupling device and the vibration device.

  26. The training system according to any one of the preceding clauses, wherein the frame includes a seating member, and the cycle axis is movable in a vibration mode with respect to the seating member.

  27. The training system according to any of the preceding clauses, wherein the cycling device is swingably connected to the frame such that the cycle axis is movable with respect to the frame in a vibration mode.

  28. The training system according to any one of the preceding clauses, wherein the cycling device is connected to the frame via a swing member.

  29. The training system according to any of the preceding clauses, wherein the rocking member comprises a longitudinal axis.

  30. The training system according to any of the preceding clauses, wherein the swing member is swingably connected to the frame at a first connection point on the swing member.

  31. The training system according to any of the preceding clauses, wherein the vibration device is connected to the swing member at a second connection point on the swing member.

  32. The training system according to any of the preceding clauses, wherein the first connection point and the second connection point are arranged at a predetermined distance from each other in the direction of the longitudinal axis.

  33. The training system according to any of the preceding clauses, wherein the cycling device is connected to the rocking member at a third connection point of the rocking member.

  34. According to any of the preceding clauses, the third connection point is arranged at a distance farther from the first connection point than the second connection point is located from the first connection point in the direction of the longitudinal axis. Training system.

  35. According to any of the preceding clauses, the second connection point is arranged at a distance farther from the first connection point than the third connection point is located from the first connection point in the direction of the longitudinal axis. Training system.

  36. According to any of the preceding clauses, the second connection point is arranged from the first connection point in the direction of the longitudinal axis at the same distance as the third connection point is located from the first connection point. Training system.

  37. The training system according to any of the preceding clauses, wherein a damper is connected to the swing member at a fourth connection point on the swing member.

  38. According to any of the preceding clauses, the third connection point is arranged at a distance farther from the first connection point than the fourth connection point is located from the first connection point in the direction of the longitudinal axis. Training system.

  39. Any of the preceding clauses wherein the fourth connection point is arranged at a distance farther from the first connection point than the third connection point is located from the first connection point in the direction of the longitudinal axis. Training system.

  40. According to any of the preceding clauses, the third connection point is located from the first connection point in the direction of the longitudinal axis at the same distance as the fourth connection point is located from the first connection point. Training system.

  41. The swing member includes a swing portion extending from one side of the frame, and the first connection point and / or the second connection point and / or the third connection point and / or the fourth connection point are connected to the swing member. The training system according to any one of the preceding clauses arranged on the moving part.

  42. The training system according to any of the preceding clauses, wherein the vibration device comprises a crankshaft connected to a rocking member.

  43. The training system according to any of the preceding clauses, wherein the crankshaft is connected to the swing member at a second connection point.

  44. The training system according to any of the preceding clauses, wherein the training system comprises a drive for driving the crankshaft.

  45. The training system according to any of the preceding clauses, wherein the drive device comprises an electric motor coupled to the crankshaft.

  46. The training system according to any of the preceding clauses, wherein the vibration device is driven by a cycling device.

  47. The training system according to any of the preceding clauses, wherein the crankshaft is driven by a cycling device.

  48. The training system according to any of the preceding clauses, wherein the drive device comprises a flywheel coupled to the crankshaft.

  49. The training system according to any one of the preceding clauses, wherein the flywheel is coupled to the crankshaft so that the rotational movement of the flywheel is transmitted to the crankshaft.

  50. The training system according to any of the preceding clauses, wherein the flywheel is connected to the crankshaft by an endless drive.

  51. The training system according to any of the preceding clauses, wherein the flywheel is connected to the crankshaft by at least one endless drive.

  52. The training system according to any of the preceding clauses, wherein the flywheel is connected to the crankshaft with only one endless drive.

  53. The training system according to any of the preceding clauses, wherein the flywheel is connected to the crankshaft via a gear device.

  54. The training system according to any of the preceding clauses, wherein the flywheel is driven by a cycling device.

  55. The training system according to any of the preceding clauses, wherein the cycling device is connected to the flywheel and drives the flywheel.

  56. The training system according to any of the preceding clauses, wherein the flywheel is coupled to a cycling device such that the rotational movement of at least one cycle member is transmitted to the flywheel.

  57. The training system according to any of the preceding clauses, wherein the cycling device is connected to the flywheel by an endless circulator.

  58. The training system according to any of the preceding clauses, wherein the cycling device is connected to the flywheel by at least one endless circulator.

  59. The training system according to any of the preceding clauses, wherein the cycling device is connected to the flywheel with only one endless circulator.

  60. The training system according to any of the preceding clauses, wherein the flywheel comprises a first coupling member that engages the endless drive.

  61. The training system according to any of the preceding clauses, wherein the flywheel comprises a second coupling member that engages the endless drive.

  62. The training system according to any of the preceding clauses, wherein the cycling device is connected to the flywheel via a gear device.

  63. The training system according to any of the preceding clauses, wherein the cycling device comprises a third coupling member that engages the endless circulator.

  64. The training system according to any of the preceding clauses, wherein the cycling device comprises a cycle disk configured to rotate about the cycle axis when at least one cycle member is rotated about the cycle axis.

  65. The training system according to any of the preceding clauses, wherein the cycle disk comprises a third coupling member.

  66. The training system according to any of the preceding clauses, wherein the vibration device includes a fourth connecting member that engages with the endless circulator.

  67. The training system according to any one of the preceding clauses, wherein the crankshaft is configured by a fourth connecting member.

  68. The vibration device includes at least one eccentric weight pivotably connected to the swing member, and an electric drive that rotates the eccentric weight so that the swing member moves in a vibration mode. A training system according to any of the above.

69. The vibration device
A disk-shaped member connected to a cycling device so as to be rotatable about the cycle axis, and a disk-shaped member having a protrusion whose peripheral edge extends in a substantially radial direction;
A pressing device according to any of the preceding clauses, comprising: a pressing device that presses against the periphery and causes at least one cycling member to move in a vibrating manner when the disk-shaped member is rotated about a cycle axis. Training system.

  70. The training system according to any of the preceding clauses, wherein the pressing device is configured to press the pressing member against the periphery of the disk-shaped member.

  71. The training system according to any of the preceding clauses, wherein the pressing device is configured such that the pressing member can be displaced only in a radial direction with respect to the cycle axis.

  72. The training system according to any of the preceding clauses, wherein the cycling device is configured to drive the endless body and vibrate the endless body so that the at least one cycling member moves in a vibrating manner.

  73. The training system according to any one of the preceding clauses, wherein the vibration device is configured to drive the impact member in a vibration mode with respect to the endless body.

  74. A training system according to any of the preceding clauses, wherein the training system comprises an adjustable cycling resistor that provides resistance to and adjusts the rotation of the cycling member about the cycle axis.

  75. The training system according to any of the preceding clauses, wherein the cycle axis is fixed to the frame.

  76. The training system according to any of the preceding clauses, wherein the cycle axis is a virtual cycle axis.

  77. The training system according to any one of the preceding clauses, wherein the cycle axis is a virtual cycle axis, and the cycling device is configured to rotate about the virtual cycle axis.

  78. The training system according to any of the preceding clauses, wherein the cycle axis is a virtual cycle axis that defines a cycle center, and the cycling device is configured to rotate about the cycle center.

  79. The training system according to any of the preceding clauses, wherein the cycle axis is a virtual axis that defines a cycle center around which the cycling device rotates in use.

80. A frame for positioning the training system on the surface when in use;
At least one cycling member configured to rotate about a cycle center;
A training system for training a user's body part, comprising: a vibration device that moves at least one cycling member in a vibrating manner.

  81. 60. The training system of clause 59, comprising one or more features consisting of one or more arbitrary preceding clauses.

  82. The training system according to any one of the preceding clauses, wherein the cycling device is configured to rotate in a substantially circular path around the cycle axis and / or the virtual cycle axis and / or the cycle center.

  83. The training system according to any one of the preceding clauses, wherein the cycling device is configured to rotate in a substantially elliptical orbit around the cycle axis and / or the virtual cycle axis and / or the cycle center.

  84. The cycling apparatus according to any of the preceding clauses, wherein the cycling device is configured to rotate in a substantial ellipse around the cycle axis and / or the virtual cycle axis and / or the cycle center such that the movement simulates Nordic ski movement. Training system.

  85. The preceding clause, wherein the cycling device is configured to pivot in a substantially elliptical manner around the cycle axis and / or virtual cycle axis and / or the cycle center so that the motion simulates Nordic skiing motion using the user's foot A training system according to any of the above.

  86. The training system according to any of the preceding clauses, comprising at least one hand rod configured to be engaged by a user and configured to vibrate the at least one hand rod.

  87. The training system according to any of the preceding clauses, comprising two hand rods configured to be engaged by a user and configured to vibrate the two hand rods.

  88. Training system according to any of the preceding clauses, wherein the training system comprises an additional vibration device for vibrating at least one movable hand rod and / or two movable hand rods.

  89. The training system according to any of the preceding clauses, wherein the vibration device is configured to vibrate at least one movable hand rod and / or two movable hand rods.

  90. The training system according to any of the preceding clauses, wherein the hand rod is movable so that its movement simulates Nordic skiing movement.

  91. The training system according to any of the preceding clauses, wherein the hand rod is movable so that the movement simulates the movement of Nordic skiing using the user's hand.

  92. A training system according to any of the preceding clauses, wherein the training system comprises one or any combination of features disclosed in the detailed description and / or drawings.

  93. A method for training a body part of a user, comprising rotation of at least one cycle member about a cycle axis of a training system according to any of the preceding clauses.

  94. A method for training a body part of a user, comprising rotation of at least one cycle member about the cycle center of the training system according to any of the preceding clauses.

  95. Use of the training system described in any of the preceding clauses 1-92.

  It will be apparent to those skilled in the art that the training system according to the present invention, the method and use of the training system are possible without departing from the scope of protection defined by this application.

DESCRIPTION OF SYMBOLS 1 Training system 3 Surface 2 Frame 5 Cycling member 4 Cycling device 6 Cycle shaft 7 Vibrating device 8 Seating member 9 Swing member 10 Longitudinal axis 11 First connection point 12 Second connection point 13 Third connection point 16 Swing Moving part 15 Damper 17 Crankshaft 18 Drive device 19 Electric motor 20 Flywheel 21 Gear device 22 Vibration motor 24 Disc shaped member 25 Perimeter 26 Protrusion 27 Press device 28 Press member 29 Spring 30 Cycle disk 31 Solenoid 32 Impact member 33 Adjustable cycling Resistor 34 User support 36 Connecting rod 37 Flywheel shaft 38 Endless drive body 39 Endless circulation body 42 Gear controller 43 Control panel 44 Control unit 45 Spring 46 Damping support body 47 First guide device 4 Second guide device 49 Member shaft 50 Engaging member 51 First connecting member 53 Third connecting member 54 Fourth connecting member 57 Pivoting shaft 64 Connecting device 65 Connecting roller 66 Connecting position 67 Unconnected position 68 Applying tension Device 69 First tension applying roller 70 Second tension applying roller 72 Roller support 73 Connection bar 75 Connection control member 76, 77 Rotating shaft 78 Bearing 79 Tension application guide 81 Damping joint 82 First wheel 83 Second wheel 84 Hand rod 85 Foot support 86, 87, 88 Pivot shaft 89 Connecting member 90 Member id 91 Connecting member 92, 93 Eccentric weight 95 First engagement region 96 Second engagement region

Claims (28)

A training system for training a user's body part,
A frame used to place the training system on a surface in use;
A cycling device comprising at least one cycling member configured to pivot about a cycle axis;
A training system comprising: a vibrating device for moving the at least one cycling member in a vibrating manner.   The training system according to claim 1, wherein the vibration device is configured to move the cycle axis in a vibrating manner.   The training system according to claim 1, wherein the cycle axis is configured to move in a vibrating manner with respect to the frame.   The training system according to any one of claims 1 to 3, wherein the cycling device is connected to the frame such that the cycle axis is driven in a vibrating manner with respect to the frame.   The training system according to any one of claims 1 to 4, wherein the vibration device includes a crankshaft coupled to the cycle shaft and configured to move the cycle shaft in a vibrating manner.   The crankshaft comprises a crankshaft shaft, the cycle shaft is located away from the crankshaft shaft, and the crankshaft is configured to rotate about the crankshaft shaft. Training system.   The training system according to claim 5 or 6, wherein the crankshaft is connected to the claim such that the crankshaft shaft is located at a position where the crankshaft shaft is substantially fixed with respect to the frame.   The training system according to any one of claims 5 to 7, wherein the crankshaft includes a first eccentric weight that compensates for a force induced by a vibration motion of the cycle axis.   9. The cycling device according to any of claims 1 to 8, wherein the cycling device comprises a cycle disk configured to rotate about the cycle axis when the at least one cycling member rotates about the cycle axis. The described training system.   The training system of claim 9, wherein the cycle disk engages an endless body.   The training system according to claim 9 or 10, wherein the vibration device is configured to move the cycle disk in a vibrating manner.   The training system according to claim 11 in combination with any of claims 5 to 8, wherein the crankshaft comprises a second eccentric weight that compensates for the force induced by the oscillatory motion of the cycle disk.   The training system according to claim 9 or 10, wherein the cycle axis is connected to the cycle disk via a damping joint that reduces transmission of vibration from the cycle axis to the cycle disk.   The training system of claim 13, wherein the damping joint comprises an elastic material that reduces transmission of oscillatory motion of the cycle axis to the cycle disk.   15. A training system according to claim 13 or 14, wherein the damping joint comprises an elastic bushing that reduces the transmission of the oscillating motion of the cycle axis to the cycle disk, the elastic bushing surrounding the cycle axis.   The training system according to any one of claims 13 to 15, wherein the damping joint includes a rubber bushing that reduces transmission of vibration motion of the cycle shaft to the cycle disk, and the rubber bush surrounds the cycle shaft.   The training system according to any one of claims 10 to 16, wherein the training system includes a tension applying device that applies tension to an endless body with which the cycle disk is engaged.   18. The training system of claim 17, wherein the tensioning device engages an endless body and is connected to the crankshaft so that the tensioning device moves in reverse phase when in use when contrasted with the oscillatory motion of the cycle axis.   The tensioning device includes at least one tensioning roller that engages an endless body, and a roller support, the roller support connecting the at least one tensioning roller to a crankshaft, 19. A training system according to claim 17 or 18, wherein the training system moves in reverse phase when in use when compared to vibrational motion.   The cycle disk is engaged with the endless body in the first engagement area and the second engagement area, and the tension applying guide is engaged with the endless body between the first engagement area and the second engagement area. The training system according to any one of claims 10 to 19, wherein   The training system according to claim 20, wherein the first engagement region and the second engagement region are arranged at a predetermined distance from each other.   The training system according to any one of claims 1 to 21, further comprising a driving device for driving the vibration device.   23. The training system of claim 22, wherein the drive device is configured to be driven by the cycling device.   The training system according to claim 22 or 23, comprising a connecting device for connecting the driving device to the vibrating device and disconnecting the driving device from the vibrating device.   The training system according to claim 24, wherein the coupling device includes a coupling control member that controls coupling and separation between the coupling device and the vibration device.   26. A training system according to any of claims 1 to 25, comprising one or any combination of the features of clauses 1 to 92.   27. A method of training a body part of a user, wherein the body part is used to rotate the at least one cycle member about the cycle axis of the training system according to any of claims 1 to 26.   Use of a training system according to any of claims 1 to 26.

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