Exercise device with continuous, flexible pulling member

Abstract

An exercise device uses a guide member that is rotatably arranged on a shaft. A continuous, flexible pulling member wraps around the guide member and causes the guide member to rotate when the continuous, flexible pulling member is pulled. Two rotatable metal discs are arranged coaxially with the guide member on the shaft, one rotatable metal disc being arranged on each side of the guide member. A gear set is operatively connecting the guide member and the two rotatable metal discs. A magnetic cylinder is arranged substantially parallel to the shaft between the two rotatable metal discs such that a magnetic field passes through radially outer areas of the rotatable metal discs in a substantially axial orientation. The rotatable metal discs and the magnetic cylinder form an eddy current brake which counteracts a pulling motion on the continuous, flexible pulling member.

Claims

1. An exercise device, comprising: a guide member rotatably arrange on a shaft; a continuous, flexible pulling member which wraps around the guide member and causes the guide member to rotate when the continuous, flexible pulling member is pulled; two rotatable metal discs arranged coaxially with the guide member on the shaft, one rotatable metal disc of the two rotatable metal discs being arranged on each side of the guide member; a gear set operatively connecting the guide member and the two rotatable metal discs; and a magnetic cylinder arranged substantially parallel to the shaft between the two rotatable metal discs such that a magnetic field passes through radially outer areas of the rotatable metal discs in a substantially axial orientation, wherein the rotatable metal discs and the magnetic cylinder form an eddy current brake which counteracts a pulling motion on the continuous, flexible pulling member, and wherein the magnetic cylinder comprises two magnets which are adapted to be moved axially relative to each other by a regulator, thereby causing the eddy current brake to become more or less effective based on an axial position of the magnets within the magnetic cylinder.

2. The exercise device as in claim 1, further comprising a carrier plate and a support plate, the carrier plate and the support plate being arranged on opposite sides of the guide member.

3. The exercise device as in claim 2, wherein the carrier plate and the support plate are arranged between the guide member and the rotatable metal discs and wherein the shaft reaches through the carrier plate and the support plate.

4. The exercise device as in claim 3, wherein the shaft is fixedly connected to the rotatable metal discs and rotatably connected to the carrier plate, the support plate, and the guide member by bearings.

5. The exercise device as in claim 1, wherein the gear set comprises a plurality of gears with a predetermined transmission ratio between the guide member and the two rotatable metal discs.

6. The exercise device as in claim 5, wherein the predetermined transmission ratio between the guide member and the two rotatable metal discs is 1:12.

7. The exercise device as in claim 1, wherein the two magnets are cylinder-shaped and comprise pins which engage a guide channel in the regulator, and wherein relative movement of the magnets is affected by rotating the regulator.

8. The exercise device as in claim 1, further comprising a mounting for attaching the device.

9. The exercise device as in claim 1, further comprising a pressure roller arranged to push the continuous, flexible pulling member into the guide member.

10. An exercise device, comprising: a guide member rotatably arrange on a shaft; a continuous, flexible pulling member which wraps around the guide member and causes the guide member to rotate when the continuous, flexible pulling member is pulled; two rotatable metal discs arranged coaxially with the guide member on the shaft, one rotatable metal disc of the two rotatable metal discs being arranged on each side of the guide member; a gear set operatively connecting the guide member and the two rotatable metal discs; and a magnetic cylinder arranged substantially parallel to the shaft between the two rotatable metal discs such that a magnetic field passes through radially outer areas of the rotatable metal discs in a substantially axial orientation, wherein the rotatable metal discs and the magnetic cylinder form an eddy current brake which counteracts a pulling motion on the continuous, flexible pulling member, and wherein the gear set comprises a plurality of gears, the plurality of gears providing a predetermined transmission ratio between the guide member and the two rotatable metal discs.

11. The exercise device as in claim 10, further comprising a carrier plate and a support plate, the carrier plate and the support plate being arranged on opposite sides of the guide member.

12. The exercise device as in claim 11, wherein the carrier plate and the support plate are arranged between the guide member and the rotatable metal discs and wherein the shaft reaches through the carrier plate and the support plate.

13. The exercise device as in claim 12, wherein the shaft is fixedly connected to the rotatable metal discs and rotatably connected to the carrier plate, the support plate, and the guide member by bearings.

14. The exercise device as in claim 10, wherein the predetermined transmission ratio between the guide member and the two rotatable metal discs is 1:12.

15. The exercise device as in claim 10, further comprising a pressure roller arranged to push the continuous, flexible pulling member into the guide member.

16. An exercise device, comprising: a guide member rotatably arrange on a shaft; a continuous, flexible pulling member which wraps around the guide member and causes the guide member to rotate when the continuous, flexible pulling member is pulled; two rotatable metal discs arranged coaxially with the guide member on the shaft, one rotatable metal disc of the two rotatable metal discs being arranged on each side of the guide member; a gear set operatively connecting the guide member and the two rotatable metal discs; a magnetic cylinder arranged substantially parallel to the shaft between the two rotatable metal discs such that a magnetic field passes through radially outer areas of the rotatable metal discs in a substantially axial orientation; and a carrier plate and a support plate, the carrier plate and the support plate being arranged on opposite sides of the guide member, wherein the rotatable metal discs and the magnetic cylinder form an eddy current brake which counteracts a pulling motion on the continuous, flexible pulling member, and wherein the carrier plate and the support plate are arranged between the guide member and the rotatable metal discs and wherein the shaft reaches through the carrier plate and the support plate.

17. The exercise device as in claim 16, wherein the shaft is fixedly connected to the rotatable metal discs and rotatably connected to the carrier plate, the support plate, and the guide member by bearings.

18. The exercise device as in claim 16, further comprising a pressure roller arranged to push the continuous, flexible pulling member into the guide member.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Additional objectives, features, advantages, and possible applications of the device can be gleaned from the following description of an exemplary embodiment on the basis of the drawings.

(2) FIG. 1 is a perspective view of an exercise device in in its assembled state.

(3) FIG. 2a and FIG. 2b provide a partially broken perspective view and a frontal view of the gear assembly of the device.

(4) FIG. 3 is an additional—partly assembled—perspective view of the device.

(5) FIG. 4 depicts the device with rotating metal/brake discs.

(6) FIGS. 5a, 5b, 5c, and 5d show details of a magnetic cylinder and a regulator.

(7) FIG. 6 is a schematic drawing of how two magnets are positioned along the metal/brake discs in the normal position of the regulator.

(8) FIG. 7a and FIG. 7b depict both ends of a pulling member with a cylindrical connector ring.

DETAILED DESCRIPTION

(9) FIG. 1 shows an exemplary exercise device which is of very compact construction. The device comprises a guide member 2 around which a continuous pulling member (rope) 1 is wrapped. The continuous pulling member 1 can be pulled out of the device or guide member 2 against the resistance created by an eddy current brake. The pulling member 1 may be a rope, belt, band, chain, tube, or other similar flexible pulling member designed to be continuous, i.e. without a beginning and an end.

(10) The device depicted schematically in FIG. 2a and FIG. 2b comprises a guide member 2 around which the pulling member 1 is wrapped. This guide member 2 is driven by the pulling member 1 when the exercise is performed. The rotation of the guide member 2 causes a rotation of a first gearwheel 3 that is arranged on the guide member 2, and which is preferably affixed to the guide member 2 with bolts. A second gearwheel 4 is driven by the first gearwheel 3. The second gearwheel 4 is fixed opposite a third gearwheel 6 on a gear shaft 5. The third gearwheel 6 drives a fourth gearwheel 7. The fourth gearwheel 7 drives a fifth gearwheel 8, which is fixed to a shaft 9. The shaft 9 is supported by bearings 10 and 11 supports the guide member 2. The gearwheels 3, 4, 6, 7, and 8 form a gear set 32. Based on their construction and configuration in the present exemplary embodiment, a ratio of 12:1 (one revolution of the guide member 2 causes 12 revolutions of the shaft 9) is provided with the guide member 2 and the shaft 9 counter-rotating.

(11) As shown in FIG. 3, the device may comprise a mounting 12 (mounting bracket) to affix the device to suitable suspension points.

(12) On either side of the guide member 2 are positioned a carrier plate 13 and a support plate 14. By means of a bearing 15 and an opposing bearing (not shown), the shaft 9 is supported in the carrier plate 13 and the support plate 14 while being able to turn freely.

(13) A pressure roller (pressing means) 17 is provided on the front, which pushes the pulling member 1 into the guide member 2 in order to prevent slippage between the pulling member 1 and the guide member 2. The pressure roller 17 is mounted on the gear shaft 5 by bearing 18 and its opposing bearing (not shown) so as to be freely rotatable. The bearings 18 are positioned one on either side of the pressure roller 17. The pressure roller 17 can be driven in such a manner as to rotate at almost precisely the speed of the pulling member 1, and whereby slippage of the pulling member 1 is prevented by the addition of more traction area on the pulling member 1 and less pressure. The benefit of this is less wear on the pulling member 1.

(14) Also visible in FIG. 3 are the regulator (adjustment wheel) 20 and the magnetic cylinder 21.

(15) FIG. 4 depicts the two rotating metal/brake discs 22 and 23, which are affixed to the shaft 9 by the nut 24 and an opposing nut. The configuration of the gearwheels 3, 4, 6, 7, 8 described above allows the discs 22 and 23 to rotate with the shaft 9 in a ratio to the guide member of 12:1. When the device is in use, the inner surfaces of the outer edges of the metal/brake discs 22 and 23 rotate very closely past the magnetic cylinder 21. In this embodiment of the device, the largest braking effect is achieved by the axial penetration of the discs 22 and 23 by the magnetic field of the magnetic cylinder 21.

(16) FIGS. 5a-d depict a specific embodiment of the magnetic cylinder 21 and the regulator 20. The magnetic cylinder 21 may comprise two spring-loaded cylindrical magnets 27, 28 (FIGS. 5b, 5d). The two magnets 27, 28 are forced apart by a spring 26. A pin 29, 30 (FIG. 5d) is provided on each magnet 27, 28. The pins 29, 30 project into guide slots on the regulator 20. By turning the regulator 20, the magnets 27, 28 are moved toward or away from one another.

(17) FIG. 6 depicts schematically how the two magnets 27, 28 are positioned next to the metal/brake discs 22, 23 in the normal position of the regulator 20. The eddy current brake is regulated by the regulator 20. The regulation is the result of the interaction between the magnets 27, 28 and the rotating metal/brake discs 22, 23.

(18) FIGS. 7a, 7b depict the two ends of the pulling member 1, which are formed (by means of pressure, heat, and friction) such that they are fitted into a cylinder-shaped connector ring 31 form-fittingly and force-fittingly. The connector ring 31 is made of a strong and sturdy material, and preferably has a smaller diameter than that of the pulling member 1. The connection itself is made using an adhesive.