(19)
(11)EP 2 859 920 B1

(12)EUROPEAN PATENT SPECIFICATION

(45)Mention of the grant of the patent:
13.05.2020 Bulletin 2020/20

(21)Application number: 14185240.0

(22)Date of filing:  17.09.2014
(51)International Patent Classification (IPC): 
A63B 21/005(2006.01)
A63B 21/00(2006.01)
A63B 22/06(2006.01)
A63B 23/035(2006.01)
A63B 22/00(2006.01)
A63B 21/012(2006.01)
A63B 22/20(2006.01)
A63B 23/12(2006.01)

(54)

Exercise equipment

Übungseinrichtung

Équipement d'exercice


(84)Designated Contracting States:
AL AT BE BG CH CY CZ DE DK EE ES FI FR GB GR HR HU IE IS IT LI LT LU LV MC MK MT NL NO PL PT RO RS SE SI SK SM TR

(30)Priority: 18.09.2013 US 201361879151 P
21.02.2014 US 201414185938

(43)Date of publication of application:
15.04.2015 Bulletin 2015/16

(60)Divisional application:
18175802.0 / 3403699

(73)Proprietor: Preventive Medical Health Care Co., Ltd.
Taoyuan County 33393 (TW)

(72)Inventor:
  • Yeh, Ching-Yu
    Taichung (TW)

(74)Representative: Lang, Christian 
LangPatent Anwaltskanzlei Ingolstädter Straße 5
80807 München
80807 München (DE)


(56)References cited: : 
WO-A2-00/67851
TW-A- 201 000 168
US-A- 5 094 447
US-A1- 2002 094 912
WO-A2-2011/017250
TW-U- M 429 493
US-A- 5 735 778
US-A1- 2011 275 481
  
      
    Note: Within nine months from the publication of the mention of the grant of the European patent, any person may give notice to the European Patent Office of opposition to the European patent granted. Notice of opposition shall be filed in a written reasoned statement. It shall not be deemed to have been filed until the opposition fee has been paid. (Art. 99(1) European Patent Convention).


    Description

    BACKGROUND


    Technical Field



    [0001] The present invention relates to an exercise equipment.

    Description of Related Art



    [0002] Exercise equipment make raining day and limited ground no longer be problems of doing exercise. With the increase demand for exercise equipment, various types of exercise equipment for training different parts of user's body are provided.

    [0003] In general, user should overcome the resistance generated from the exercise equipment for training the shape of body. However, the resistance device provides the resistance by rub two components. Therefore, the resistance device of the exercise equipment usually be broken easily. For solving this issue alternative designs are known. For example, document US 2002/094912 A1 refers to a magnet exercise tube consisting of a large outer magnet tube, an in-between separation plastic tube and a small inner magnet tube, wherein each magnet tube consists of numerous O-ring shaped magnets, and wherein the small inner magnet tube can slide loosely inside the in-between plastic tube, such that a resistive force will be created because of the attractive force or repelling force between the O-ring shaped magnets of the small inner magnet tube and the large outer magnet tube. Further, from the Taiwanese utility model TW M 429 493 U an exercise equipment is known, which includes a magnetic resistance device comprising a cylinder case filled with a magneto-rheological fluid (MRF), wherein a conductive coil unit is mounted on one end of a piston rod that can be moved into and out of the MRF. When the conductive coil unit is moved into the cylinder case it can generate a magnetic field around in accordance with the current conducting principle of electromagnetic induction, wherein this magnetic field causes solidification of the surrounding MRF, which hence generates a resistance force to the movement of the piston rod. Another device using the resistance generated by a rheological fluid exposed to a magnetic field is known from document WO 00/67851 A2. Furthermore, document WO 2011/017250 A2 discloses a training system which uses a translatory motion along a movement path against a counteracting resistance and includes a velocity-independent resistance provided by a mass coupled to a carriage acting against gravitational forces and a velocity-dependent resistance provided by an eddy current resistance caused by the interaction of an electrically conductive structure encountering relative motion with a magnetic field, wherein the electrically conductive structure is secured to a rail of a frame structure and a magnetic field is provided by one or more permanent magnets secured to a carriage structure, wherein a relative movement along the rail results in a velocity-dependent resistance to the movement.

    SUMMARY



    [0004] According to one aspect of the present disclosure, an exercise equipment includes a base, an operating device and a magnetic resistance device with the features of claim 1. The operating device is movably disposed on the base. The magnetic resistance device is connected to the operating device and the base, wherein the magnetic resistance device is for providing a magnetic resistances in accordance with an operation of the operating device.

    [0005] According to the exercise equipment of the foregoing aspect, the magnetic resistance device includes a cylinder case disposed on the base, a magnetic resistance component assembly located in the cylinder case, and a piston rod. The magnetic resistance component assembly includes at least one magnet, and at least one conductive member adjacent to the magnet, wherein one end of the piston rod is linked up with the operating device for providing a movement between the magnet and the conductive member, so that the magnetic resistance is generated. The magnet surrounds the piston rod, and the conductive member is connected to an inner wall of the cylinder case. The conductive member is made of copper, silver, aluminum or steel. In addition, the operating device can include two operating members and two pedals, wherein the operating members are pivotally connected to the base, and the pedals are disposed on the operating members respectively.

    [0006] According to the exercise equipment of the foregoing aspect, the piston rod can be a screw rod, ball screw rod or twist screw rod. When the piston rod of the magnetic resistance device is a ball screw rod, and the magnetic resistance device can further include a telescopic tube movably inserted into the cylinder case, and a ball screw cap located in the telescopic tube and is inserted by the piston rod for rotating the piston rod. When the piston rod is a gear rack, and the magnetic resistance device can further include a gear, wherein the gear is rotated by the piston rod and links up with the conductive member. When the piston rod of the magnetic resistance device is a twist screw rod, and the magnetic resistance device can further include a telescopic tube movably inserted into the cylinder case, and a twist screw cap located in the telescopic tube and is inserted by the piston rod for rotating the piston rod.

    [0007] According to the exercise equipment of the foregoing aspect, the exercise equipment can further include a resistance adjusting device for changing a relative position between the magnet and the conductive member. The resistance adjusting device can include a rotating base and an adjusting cover, wherein the conductive member is connected to the inner wall of the cylinder case via the rotating base, and the adjusting cover is rotatably connected to the cylinder case and linked up with the rotating base.

    [0008] The exercise equipment can further include a rail disposed on the base, wherein the operating device is for driving along the rail, and the rail can be circular-shaped. The magnetic resistance device can includes at least one first element and at least one second element, wherein the second element is adjacent to the first element and linked up with the operating device, wherein a movement between the first element and the second element is provided for generating the magnetic resistance. Moreover, the first element of the magnetic resistance device can be a conductive member, and the second element of the magnetic resistance device can be a magnet. Further, the magnetic resistance device can include a magnet base connected to the operating device, wherein the magnet is located on the magnet base.

    [0009] The exercise equipment can include an adjusting device for adjusting an adjacent area of the magnets and the conductive member. The adjusting device can include at least one forcing mechanisms connected to and linked up with the magnet base of the magnetic resistance device, a controlling member connected to the forcing mechanisms, and at least one restoring member connected to the magnet base for restoring the magnet base.

    [0010] The operating device can include two driving cranks pivotally connected to the base, and two pedals connected to each of the driving cranks respectively. The first element of the magnetic resistance device can be a conductive member, and a plurality of the second elements of the magnetic resistance device can be magnets, and the magnetic resistance device can further include two magnet bases connected to each of the driving cranks, wherein the magnets are located on the magnet bases. The exercise equipment can further include two adjusting devices, wherein each of the adjusting devices is connected to each of the pedals and each of the magnet bases and is for adjusting an adjacent area of the magnets located on each magnet base and the conductive member. In detail, each of the adjusting devices includes a shift shaft connected to one of the pedals, and a linking shaft linked up with the shift shaft for adjusting the adjacent area of the magnets located on each magnet base and the conductive member.

    [0011] The base can include a bottom base, a first branch base disposed on the bottom base, and a second branch base disposed on the bottom base. The operating device can include two driving cranks pivotally connected to the second branch base, two first linking cranks pivotally connected to the driving cranks respectively, two second linking cranks, one end of each of the second linking cranks pivotally connected to each of the first linking cranks, the other end of each of the second linking cranks pivotally connected to two handles respectively, and two pedals connected to the second linking cranks respectively. Furthermore, the exercise equipment can include two magnetic resistance devices, one of the magnetic resistance device is connected to the driving cranks, the other one of the magnetic resistance device is connected to the first linking cranks. The magnetic resistance device is connected to the driving cranks is a first magnetic resistance device, the first element of the first magnetic resistance device is disposed on the rail. The magnetic resistance device is connected to the first linking cranks is a second magnetic resistance device, the first element of the second magnetic resistance device is disposed on the bottom base of the base, and the second magnetic resistance comprises a plurality of the second elements linked up with the first linking cranks of the operating device.

    [0012] The exercise equipment can further include a seat base, rotatably connected to the base, wherein the seat base is rotated to an angle ϕ from each of two sides of a central axis of the base, and the angle ϕ is 0 degrees to 40 degrees.

    BRIEF DESCRIPTION OF THE DRAWINGS



    [0013] The invention can be more fully understood by reading the following detailed description of the embodiment, with reference made to the accompanying drawings as follows:

    Fig. 1 shows a schematic view of one example of an exercise equipment;

    Fig. 2 shows an enlarged view of part of the exercise equipment of Fig. 1;

    Fig. 3A is a schematic views of one using states between the magnets and the conductive member of the exercise equipment of Fig. 1;

    Fig. 3B is a schematic views of another using states between the magnets and the conductive member of the exercise equipment of Fig. 1;

    Fig. 3C is a schematic views of the other using states between the magnets and the conductive member of the exercise equipment of Fig. 1;

    Fig. 4 shows a schematic view of another example of an exercise equipment;

    Fig. 5A is a schematic view of an adjusting device of the exercise equipment of Fig. 4;

    Fig. 5B is a schematic view of the pedals of the exercise equipment of Fig. 4;

    Fig. 6A is schematic views of one using states between the magnets and the conductive member of the exercise equipment of Fig. 4;

    Fig. 6B is schematic views of another using states between the magnets and the conductive member of the exercise equipment of Fig. 4;

    Fig. 6C is schematic views of the other using states between the magnets and the conductive member of the exercise equipment of Fig. 4;

    Fig. 7A shows a schematic view of a first example of the adjacent relationships between the magnet and the conductive member;

    Fig. 7B shows a schematic view of a second example of the adjacent relationships between the magnet and the conductive member;

    Fig. 7C shows a schematic view of a third example of the adjacent relationships between the magnet and the conductive member;

    Fig. 7D shows a schematic view of a fourth example of the adjacent relationships between the magnet and the conductive member;

    Fig. 7E shows a schematic view of a fifth example of the adjacent relationships between the magnet and the conductive member;

    Fig. 8 shows a schematic view of yet another example of an exercise equipment;

    Fig. 9 shows a schematic view of still another example of an exercise equipment;

    Fig. 10 shows a schematic view of an exercise equipment according to an embodiment of the present disclosure;

    Fig. 11 shows a cross-sectional view of the magnetic resistance device of Fig. 10;

    Fig. 12 shows a schematic view of an exercise equipment according to another embodiment of the present disclosure;

    Fig. 13A shows a cross-sectional view of one magnetic resistance device and the resistance adjusting device of the exercise equipment of Fig. 12;

    Fig. 13B shows a cross-sectional view of the magnetic resistance device and the resistance adjusting device along line 13B-13B of Fig. 13A;

    Fig. 13C shows a cross-sectional view of another state of the magnetic resistance device and the resistance adjusting device of Fig. 13B;

    Fig. 14 show a schematic views of a magnetic resistance device of an exercise equipment according to further another embodiment of the present disclosure;

    Fig. 15 show a schematic views of a magnetic resistance device of an exercise equipment according to still another embodiment of the present disclosure;

    Fig. 16 shows a schematic views of a magnetic resistance device of an exercise equipment according to still another embodiment of the present disclosure;

    Fig. 17 show a schematic views of a magnetic resistance device of an exercise equipment according to still another embodiment of the present disclosure;

    Fig. 18 shows a schematic view of an exercise equipment 1100 according to still another embodiment of the present disclosure;

    Fig. 19 shows a schematic view of an exercise equipment according to yet another embodiment of the present disclosure;

    Fig. 20 shows a schematic view of an exercise equipment according to still another embodiment of the present disclosure;

    Fig. 21A shows a vertical view of a using state of the exercise equipment of Fig. 20; and

    Fig. 21B shows a vertical view of another using state of the exercise equipment of Fig. 20.


    DETAILED DESCRIPTION



    [0014] Fig. 1 shows a schematic view of an exemplary exercise equipment 100. In Fig. 1, the exercise equipment 100 is an indoor bicycle, and includes a base 110, two rails 120, an operating device 130 and a magnetic resistance device 140.

    [0015] In detail, the base 110 includes a bottom base 111, a first branch base 112 and a second branch base 113. One end of each of the first branch base 112 and the second branch base 113 are disposed on the bottom base 111. The other end of the first branch base 112 is connected to a seat base 114, and the other end of the second branch base 113 is connected to a handle 115. Each of the first branch base 112 and the second branch base 113 can be telescopic, that is, the height of each of the first branch base 112 and the second branch base 113 can be adjusted.

    [0016] The rails 120 are disposed on two sides of the base 110. In Fig. 1, the rails 120 are circular-shaped, but is not limited thereto. (Only one rail is shown in Fig. 1)

    [0017] The operating device 130 is for driving along the rails 120. In Fig. 1, the operating device 130 includes two driving cranks 131 and two pedals 132 (only one driving crank and one pedal be labelled in Fig. 1 and will be described herein). One end of the driving crank 131 is pivoted connected to the first branch base 112 of the base 110, the pedal 132 is connected to the other end of the driving crank 131. The user can step the pedals 132 for linking up the driving cranks 131 along the rails 120.

    [0018] The magnetic resistance device 140 is for providing a magnetic resistances in accordance with an operation of the operating device 130. The magnetic resistance device 140 includes two first element disposed on each rail 120, and at least two second elements adjacent to each first element and linked up with the operating device 130 for moving along the rail 120, wherein a movement between the first element and the second element is provided for generating the magnetic resistance. In detail, the first elements of the magnetic resistance device 140 are conductive members 143, wherein the conductive member 143 can be made of copper, silver, aluminum or steel, but is not limited thereto. The second element of the magnetic resistance device 140 is a plurality of magnets 142. The magnetic resistance device 140 further includes two magnet bases 141. Each of the magnet bases 141 is connected to each driving crank 131, wherein the magnets 142 are located on the magnet bases 141. In Fig. 1, the magnets 142 are located on the inner wall of each magnet base 141 which adjacent to the side of the conductive member 143. When the user drive the driving cranks 131 via the pedals 132, the magnet bases 141 can be linked up and for providing the movement between the magnets 142 and the conductive member 143, so that the magnetic resistance can be generated. By directly generating the magnetic resistance, the exercise equipment 100 is an inertialess equipment, so that the security can be increased during using. Moreover, the magnets 142 are adjacent to the conductive member 143 for generating the magnetic resistance, so that the magnets 142 would not be directly contacted to the conductive member 143, and the magnetic resistance device 140 would not be broken easily.

    [0019] Fig. 2 shows an enlarged view of part of the exercise equipment 100 of Fig. 1. The exercise equipment 100 can include an adjusting device 150 for adjusting an adjacent area of the magnets 142 and the conductive members 143. In detail, the adjusting device 150 includes two forcing mechanisms 151, two restoring members 152 and a controlling member 153 (shown in Fig. 1). Each forcing mechanisms 151 is connected to and linked up with each magnet base 141 of the magnetic resistance device 140, and each restoring member 152 connected to each magnet base 141 for restoring the magnet base 141. The controlling member 153 is connected to the forcing mechanisms 151. The user can control the forcing mechanisms 151 via the controlling member 153. The forcing mechanisms 151 are steel wire ropes which can be electrically or mechanically driven via the controlling member 153, but is not limited thereto. The restoring members 152 is spring, but is not limited thereto. The controlling member 153 is disposed on the second branch base 113 of the base 110 and is adjacent to the handle 115, so that the user can easily operate the controlling member 153 during using the exercise equipment 100.

    [0020] Figs. 3A, 3B and 3C are schematic views of three using states between the magnets 142 and the conductive member 143 of the exercise equipment 100 of Fig. 1. In Fig. 3A, the adjacent area of the magnets 142 and the conductive members 143 is largest, so that the generated magnetic resistance is greatest. In Fig. 3B, the controlling member 153 is pulled by the user, and the forcing mechanisms 151 can pull the magnet bases 141 for adjusting the adjacent area of the magnets 142 and the conductive members 143. The adjacent area in Fig. 3B is smaller than the adjacent area in Fig. 3A, that is, the generated magnetic resistance from the using state in Fig. 3B is greater than the using state in Fig. 3A. In Fig. 3C, the controlling member 153 is further pulled by the user, and the magnetic resistance is further smaller than Fig. 3B. The using states from Fig. 3A to Fig. 3C, the restoring member 152 is compressed gradually. When the controlling member 153 releases the forcing mechanism 151, the restoring member 152 can restore the magnet base 141 back to the original position (as shown in Fig. 3A).

    [0021] Fig. 4 shows a schematic view of another exemplary exercise equipment 200. In Fig. 4, the base 210 includes a first branch base 212 and a second branch base 213, wherein the first branch base 212 is connected to the second branch base 213 along a cross direction. A seat base 214 is slidably connected on the first branch base 212, and the distance between the seat base 214 and the second branch base 213 is adjustable. Handles 215 can be disposed on two sides of the seat base 214 and the second branch base 213. The seat base 214 includes a bottom seat base 214a and a back seat base 214b, so that the user can sit comfortably during using the exercise equipment 200.

    [0022] In Fig. 4, two rails 220 are disposed on two sides of the second branch base 213. The operating device 230 also includes two driving cranks 231 and two pedals 232. The magnetic resistance device 240 includes two magnet bases 241, a plurality of magnets 242 and two conductive members 243. The connecting and operating relationships among the rails 220, the operating device 230 and the magnetic resistance device 240 are the same with the rails 120, the operating device 130 and the magnetic resistance device 140 in Fig. 1, and will not explain again herein.

    [0023] Fig. 5A is a schematic view of an adjusting device 250 of the exercise equipment 200 of Fig. 4. Fig. 5B is a schematic view of the pedals 232 of the exercise equipment 200 of Fig. 4. In Figs. 5A and 5B, the exercise equipment 200 further includes two adjusting devices 250 connected to each of the pedals 232 and each of the magnet bases 241 respectively (only one adjusting device 250 be illustrated in Fig. 5A). Each pedal 232 can link up with each magnet base 241 via each adjusting device 250, so that the adjacent area of the magnets 242 located on each magnet base 241 and each conductive member 243. In detail, each of the adjusting devices 250 includes a shift shaft 251 and a linking shaft 252. One end of the shift shaft 251 is connected to the pedal 232, so that the shift shaft 251 is linked up with the pedal 232. One end of the linking shaft 252 is connected to the shift shaft 251, the other end of the linking shaft 252 is connected to the magnet base 241. Therefore, the user can shift the pedal 232 for linking up the shift shaft 251, and the linking shaft 252 can also be linked up with the shift shaft 251 for moving the magnet base 241, so that the adjacent area between the magnets 242 and the conductive member 243 can be changed. Thus, the magnetic resistance can be adjusted.

    [0024] Figs. 6A, 6B and 6C are schematic views of three using states between the magnets 242 and the conductive member 243 of the exercise equipment 200 of Fig. 4. In Figs. 6A, 6B and 6C, the adjacent area of the magnets 242 and the conductive members 243 can be changed by linking up the shift shaft 251 and the linking shaft 252 via the pedal 232. When the adjacent area between the magnets 242 and the conductive members 243 is changed, the generated magnetic resistance can be adjusted.

    [0025] For generating the magnetic resistance, at least one surface of each magnet 242 and at least one surface of each conductive member 243 should be adjacent to each other. When the movement between the surface of each magnet 242 and the surface of each conductive member 243 is provided, the magnetic resistance can be generated. Figs. 7A to 7E show schematic views of different examples for the adjacent relationships (adjacent area) between the magnet 242 and the conductive member 243, wherein the magnet base 241 is not shown herein. In Fig. 7A, the magnet 242 is disposed on one inner wall of the magnet base 241, and one surface of the conductive member 243 is adjacent to the magnet 242. In Fig. 7B, the magnets 242 are disposed on two inner walls of the magnet base 241, and the conductive member 243 is located between the magnets 242. That is, two surfaces of the conductive member 243 are adjacent to the magnet 242. In Fig. 7C, the magnets 242 is U-shaped, and the conductive member 243 is embedded into the magnets 242. That is, three surfaces of the conductive member 243 are adjacent to the magnet 242. In Fig. 7D, the magnets 242 is U-shaped, and the conductive member 243 is T-shaped which be embedded into the magnets 242. Therefore, four surfaces of the conductive member 243 are adjacent to the magnet 242. In Fig. 7E, the magnets 242 is U-shaped, and the conductive member 243 is T-shaped which be embedded into the magnets 242. That is, five surfaces of the conductive member 243 are adjacent to the magnet 242. By such arrangements, the adjacent area between the conductive member 243 and the magnet 242 can be varied on demand, and different arrangements can provide different magnetic resistance.

    [0026] Fig. 8 shows a schematic view of another example of an exercise equipment 300. In Fig. 8, the base includes a bottom base 311, a first branch base 312 and a second branch base 313, wherein the first branch base 312 and a second branch base 313 are disposed on the bottom base 311. Two handles 315 are pivotally connected to two sides of the first branch base 312. The rails 320 are disposed on two sides of the second branch base 313 of the base. In Fig. 8, the rails 320 are circular-shaped, but is not limited thereto.

    [0027] In Fig. 8, the operating device 330 includes two driving cranks 331, two pedals 332, two first linking cranks 333 and two second linking cranks 334. One end of each driving crank 331 is pivotally connected to the second branch base 313, another end of each driving crank 331 is pivotally connected to one end of each first linking crank 333, and another end of each first linking crank 333 is slidably connected to the bottom base 311. Each second linking crank 334 connects each handle 315 and each first linking crank 333, so that each handle 315 is linked up with each first linking crank 333 via each second linking crank 334. Each pedal 332 is connected to each second linking crank 334 and located on each first linking crank 333, wherein the pedals are arranged parallel to the ground.

    [0028] In Fig. 8, the exercise equipment 300 includes two magnetic resistance devices, one is first magnetic resistance device 340a, the other is second magnetic resistance device 340b. The first magnetic resistance device 340a includes two magnet bases 341a, a plurality of magnets 342a and two conductive members 343a, wherein each magnet base 341a is connected to each driving crank 331, and each driving crank 331 is operated by each pedal 332 and each first linking crank 333 for linking up with each magnet base 341a, the conductive members 343a (the first elements of the first magnetic resistance device 340a) is disposed on the rails 320. Therefore, the movement between the magnets 342a located on each magnet base 341a and each conductive member 343a can be provided, so that the magnetic resistance is generated.

    [0029] The exercise equipment 300 further includes the second magnetic resistance device 340b. The second magnetic resistance device 340b includes two magnet bases 341b, a plurality of magnets (second elements) 342b and two conductive members (first elements) 343b, wherein the conductive members 343b are disposed on two sides of the bottom base 311 respectively, the magnet bases 341b are connected to one end of each first linking crank 333 respectively and is slidably disposed on two sides of the bottom base 311 respectively. The magnets 342b are located on each magnet base 341b and are adjacent to each conductive member 343b. When the user step the pedals 332, the first linking cranks 333 can be moved, and two end of each first linking cranks 333 can slide along two sides of the bottom base 311. Therefore, the magnet bases 341b can be slid along the conductive members 343b located on the two sides of the bottom base 311 for providing the movement between the magnets 342b and the conductive members 343b, and the magnetic resistance is generated.

    [0030] Moreover, the exercise equipment 300 in Fig. 8 can also include an adjusting device which for adjusting the magnetic resistance generated from the first magnetic resistance device 340a, wherein the adjusting device can be controlled via the controlling member 353 located on the first branch base 312. In this example, the adjusting device is the same as the adjusting device 150 in Fig. 1, and will not describe and illustrate again.

    [0031] Fig. 9 shows a schematic view of another example for an exercise equipment 400, wherein the exercise equipment 400 is driven by user's hands. According to the exercise equipment 400 of Fig. 9, the operating device 430 includes a driving axis member 431, two driving cranks 431 and an operating rope 433. The driving axis member 431 is disposed on the base 410, and one end of each of the driving cranks 431 pivotally connected to the driving axis member 431. The operating rope 433 is wrapped around the driving axis member 431 and one end thereof is connected to a handle 415. Each of the magnetic resistance devices 440 includes two magnet bases 441, a plurality of magnets 442 and two conductive members 443, and are the same as the foregoing example, and will not describe again herein.

    [0032] When the user pulling the handle 415, the operating rope 433 can link up with the driving cranks 432, and the driving cranks 432 is pivoted along the rails 420.

    [0033] Fig. 10 shows a schematic view of an exercise equipment 500 according to one embodiment of the present disclosure. In Fig. 10, the exercise equipment 500 includes a base 510, an operating device 520 and a magnetic resistance device 530.

    [0034] The base 510 includes a bottom base 511 and a first branch base 512. The first branch base 512 is connected to the bottom base 511. Two handles 515 are connected to two sides of the first branch base 512 respectively (only one handle 515 is shown).

    [0035] The operating device 520 is movably disposed on the bottom base 511 of the base 510. In Fig. 10, the operating device 520 includes two operating members 521 and two pedals 522. One end of each of the operating members 521 is pivotally connected to the bottom base 511, each of the pedals 512 is disposed on the other side of each of the operating members 521 respectively. The pedals 512 can be stepped for driving the operating members 511 alternately.

    [0036] Two magnetic resistance devices 530 are connected to each of the operating members 521 of the operating device 520 and the base 510 respectively, and the following description is only one magnetic resistance device 530 is mentioned. Fig. 11 shows a cross-sectional view of the magnetic resistance device 530 of Fig. 10. The magnetic resistance device 530 includes a cylinder case 531, a magnetic resistance component assembly, and a piston rod 534, wherein the magnetic resistance component assembly includes magnets 532 and a conductive member 533, the conductive member 533 is made of copper, silver, aluminum or steel. One end of the cylinder case 531 is connected to the operating member 521. The magnetic resistance component assembly is located in the cylinder case 531, wherein the conductive member 533 is connected to an inner wall of the cylinder case 531, the magnets 532 surround the piston rod 534, and the conductive member 533 is adjacent to the magnets 532. One end of the piston rod 534 is connected to the handle 515 on the first branch base 512 of the base 510, the other end of the piston rod 534 is movably surrounded by the cylinder case 531. Therefore, when the operating member 521 is alternately operated, the piston rod is pushed, so that a movement between the magnets 532 and the conductive member 533 is provided, and the magnetic resistance is generated.

    [0037] Fig. 12 shows a schematic view of an exercise equipment 600 according to another embodiment of the present disclosure. In Fig. 12, the exercise equipment 600 includes a base (not labelled), an operating device (not labelled) and a magnetic resistance device 630.

    [0038] The base includes a bottom base 611, a first branch base 612, and a second branch base 613. The first branch base 612 and the second branch base 613 are disposed on the bottom base 611. The first branch base 612 is L-shaped, wherein a seat base 614 and a cushion 616 is disposed on the first branch base 612, so that the user can sit on the seat base 614, and the user's back can be supported by the cushion 616.

    [0039] The operating device includes two operating members 621 which coaxially and pivotally connected to the first branch base 612 of the base. One end of the operating members 621 can be driven alternatively.

    [0040] Two magnetic resistance devices 630 are connected to the other end of each of the operating members 621 of the operating device and the second branch base 613 of the base respectively, and the following description is only one magnetic resistance device 630 is mentioned. In Fig. 12, magnetic resistance device 630 includes a cylinder case 631, a magnetic resistance component assembly, and a piston rod 634, wherein the magnetic resistance component assembly includes magnets 632, a conductive member 633 and a magnet base 635 (in Fig. 13A), wherein the magnet base 635 can include a plurality of layer frames and the magnets 632 can be arranged on the layer frames. The cylinder case 631 is connected to the second branch base 613, and the outer end of the piston rod 634 is connected and linked up with the other end of the operating member 621. When the operating members 621 is driven alternatively, the piston rod 634 is linked up and the movement between the magnets 632 and the conductive member 633 is provided, so that the magnetic resistance is generated.

    [0041] In order to adjust the magnetic resistance, the exercise equipment 600 further includes a resistance adjusting device (unlabeled). Fig. 13A shows a cross-sectional view of one magnetic resistance device 630 and the resistance adjusting device of the exercise equipment 600 of Fig. 12. In Fig. 13A, the resistance adjusting device includes a rotating base 636 and an adjusting cover 637. The rotating base 636 is rotably connected to the inner wall of the cylinder case 631 and a plurality of the conductive members 633 is disposed on the rotating base 636, that is, the conductive member 633 is connected to the inner wall of the cylinder case 631 via the rotating base 636. The adjusting cover 637 is rotatbly connected to the open end of the cylinder case 631, and linked up with the rotating base 636, wherein the piston rod 634 is passed through the adjusting cover 637 and inserted into the cylinder case 631. By the arrangement of the magnet base 635, the magnets 632 can be moved stably.

    [0042] Fig. 13B shows a cross-sectional view of the magnetic resistance device 630 and the resistance adjusting device along line 13B-13B of Fig. 13A. In Fig. 13B, number of the conductive members 633 is three and equally arranged on the rotating base 636. There are three magnets 632 located on each of the layer frames of the magnet base 635. When the entire side surface of each magnet 632 is faced to each conductive member 633, the magnetic resistance is largest.

    [0043] Fig. 13C shows a cross-sectional view of another state of the magnetic resistance device 630 and the resistance adjusting device of Fig. 13B. When the adjusting cover 637 is turned, the rotating base 636 is rotated and the conductive members 633 thereon is moved. Therefore, partial surface of each magnet 632 is not faced to each conductive member 633, thus, the magnetic resistance is smaller during the piston rod 634 is driven.

    [0044] Fig. 14 show a schematic views of a magnetic resistance device 730 of an exercise equipment according to further another embodiment of the present disclosure, wherein the cylinder case of the magnetic resistance device 730 will not be shown in Fig. 14. In Fig. 14, the piston rod 734 is a screw rod. The magnetic resistance component assembly includes a plurality of magnets 732, a conductive member 733 and a magnet case 738, wherein the magnets 732 and the conductive member 733 is located in the magnet case 738. The magnets 732 is connected to two inner side of the magnet case 738, and the magnets 732 on each inner side is faced to the surface of the conductive member 733. The piston rod 734 is inserted through the conductive member 733 and the magnet case 738, wherein the conductive member 733 is linked up with the piston rod 734, so that when the piston rod 734 is moved, the conductive member 733 is rotated, and the movement between the magnet 732 and the conductive member 733 is provided. Especially, the piston rod 734 is a screw rod, so that the rotational speed of the conductive member 733 can be increased, and the magnetic resistance can also be increased.

    [0045] Fig. 15 show a schematic views of a magnetic resistance device 830 of an exercise equipment according to still another embodiment of the present disclosure. In Fig. 15, the magnetic resistance device 830 includes a cylinder case 831, a magnet case 838, a magnet 832, a conductive member 833, a magnet base 835, a piston rod 834, a telescopic tube 836 and a ball screw cap 837. The magnet case 838 is fixed to one end of the cylinder case 831, wherein the conductive member 833 is disposed on the inner wall of the magnet case 838, and the magnet base 835 is located in the magnet case 838 and the magnet 832 is disposed on the magnet base 835. One surface of the conductive member 833 is adjacent to one surface of the magnet 832. The piston rod 834 is a ball screw rod which is located in the cylinder case 831, wherein one end of the piston rod 834 is inserted to the magnet case 838 and connected to the magnet base 835, so that the magnet 832 on the magnet base 835 can be rotated by the piston rod 834. The telescopic tube 836 is movably inserted into the cylinder case 831. The ball screw cap 837 is located in the telescopic tube 836 and is inserted by the piston rod 834. When the telescopic tube 836 is driven, the piston rod 834 can be rotated by the ball screw cap 837, and the magnet 832 on the magnet base 835 can be linked up. Therefore, the magnetic resistance can be generated.

    [0046] Fig. 16 shows a schematic views of a magnetic resistance device 930 of an exercise equipment according to still another embodiment of the present disclosure. In Fig. 16, the magnetic resistance device 930 includes a cylinder case (not shown), a plurality of magnets 932, a conductive member 933, a piston rod 934 and a gear 937. The magnets 932 is disposed on the inner wall of the cylinder case, and is adjacent to two surfaces of the conductive member 933. The gear 937 is located on the center of the conductive member 933. The piston rod 934 is a gear rack, and is meshed to the gear 937. When the piston rod 934 is driven, the gear 937 can be rotated and links up with the conductive member 933. Therefore, the conductive member 933 can be rotated, and the movement between the magnet 932 and the conductive member 933 is provided for generating the magnetic resistance.

    [0047] Fig. 17 show a schematic views of a magnetic resistance device 1030 of an exercise equipment according to still another embodiment of the present disclosure. In Fig. 17, the magnetic resistance device 1030 includes a cylinder case 1031, a magnet case 1038, a plurality of magnets 1032, a conductive member 1033, a piston rod 1034, a telescopic tube 1036 and a twist screw cap 1037. The magnet case 1038 is connected to the bottom base of the base of the exercise equipment (not shown) and one end of the cylinder case 1031. In the magnet case 1038, the magnets 1032 is arranged on two inner end walls of the magnet case 1038, and the magnets 1032 are adjacent to two surfaces of the conductive member 1033. The piston rod 1034 is a twist screw rod which is located in the cylinder case 1031, wherein one end of the piston rod 1034 is inserted to the magnet case 1038 and coaxially connected to the conductive member 1033, so that the conductive member 1033 can be rotated by the piston rod 1034. The twist screw cap 1037 is located in the telescopic tube 1036 and is inserted by the piston rod 1034. When the telescopic tube 1036 is driven, the piston rod 1034 can be rotated by the twist screw cap 1037, and the conductive member 1033 in the magnet case 1038 can be linked up. Therefore, the magnetic resistance can be generated.

    [0048] Fig. 18 shows a schematic view of an exercise equipment 1100 according to still another embodiment of the present disclosure. In Fig. 18, the user can sit on the seat base 1014 and pull the operating device 1120 for driving the magnetic resistance devices 1130, so that the magnetic resistance devices 1130 can provide the magnetic resistance.

    [0049] In detail, the operating device 1120 includes a handle 1121, a rope 1122 and a plurality of pulleys 1123, wherein the pulleys 1123 are pivotally connected to the base (not labelled) of the exercise equipment 1100, and the rope 1122 is wrapped through the pulleys. One end of the rope 1122 is connected to the handle 1121, and the other end of the rope 1122 is connected to the magnetic resistance devices 1130. The magnetic resistance devices 1130 is the same as any magnetic resistance devices of the foregoing embodiment of Figs. 10 - 18, and will not describe again herein.

    [0050] Fig. 19 shows a schematic view of an exercise equipment 1200 according to yet another embodiment of the present disclosure. In Fig. 19, the exercise equipment 1200 includes two magnetic resistance device, one is first magnetic resistance device 1230a, the other one is second magnetic resistance device 1230b. The first magnetic resistance device 1230a is the same as the first magnetic resistance device 340a of Fig. 8, and will not describe again herein. The second magnetic resistance device 1230b is the same as the magnetic resistance device 530 of Fig. 10, and will not describe again herein.

    [0051] Fig. 20 shows a schematic view of an exercise equipment 1300 according to still another embodiment of the present disclosure. In Fig. 20, the exercise equipment 1300 is an indoor bicycle, and a base (unlabeled) of the exercise equipment 1300 includes a bottom base 1311 which is I-shaped, and a first branch base 1312 and a second branch base 1313 which are connected to the bottom base 1311, respectively. Especially, the exercise equipment 1300 includes a seat base 1314 which is rotatably connected to the first branch base 1312 of the base.

    [0052] Fig. 21A shows a vertical view of a using state of the exercise equipment 1300 of Fig. 20. Fig. 21B shows a vertical view of another using state of the exercise equipment 1300 of Fig. 20. In detail, the seat base 1314 includes a bottom seat base 1314a and a back seat base 1314b, and the bottom seat base 1314a is rotatably connected to the first branch base 1312 of the base. A central axis of the base can be a central axis of the exercise equipment 1300, and the bottom seat base 1314a of the seat base1314 is rotated to an angle ϕ from each of two sides of the central axis of the base, and the angle ϕ is 0 degrees to 40 degrees. When the user sit on the bottom seat base 1314a and drives the exercise equipment 1300 by stepping the pedals 1332, the body of the user can be swung along with the legs. Therefore, the stepping action can be smooth for overcoming the dead point during stepping.

    [0053] Furthermore, in Figs. 20, 21A and 21B, the magnetic resistance device 1340 includes a magnet base 1341, magnets (unlabeled) and a conductive member 1343. The conductive member 1343 can be drove by the driving cranks 1331 and the pedals 1332 of the operating device 1330 for providing a movement between the conductive member 1343 and the magnets, and the magnetic resistance can be generated. The detailed operation is the same with the foregoing embodiment, and will not describe again herein.


    Claims

    1. An exercise equipment, comprising:

    a base (510);

    an operating device (520) movably disposed on the base (510); and

    at least one magnetic resistance device (530) connected to the operating device (520) and the base (510), wherein the magnetic resistance device (530) is for providing a magnetic resistance in accordance with an operation of the operating device (520), wherein the magnetic resistance device (530) comprises:

    a cylinder case (531) disposed on the base (510); and

    a magnetic resistance component assembly comprising:

    at least one magnet (532); and

    at least one conductive member (533) adjacent to the magnet (532) and being made of copper, silver, or aluminum;

    characterized in that

    the magnetic resistance component assembly is located in the cylinder case (531), and

    the magnetic resistance device (530) further comprises a piston rod (534), wherein one end of the piston rod (534) is linked up with the operating device (520) for providing a movement between the magnet (532) and the conductive member (533), so that the magnetic resistance is generated.


     
    2. The exercise equipment of claim 1, wherein the operating device (520) comprises:

    two operating members (521) pivotally connected to the base; and

    two pedals (522) disposed on the operating members respectively.


     
    3. The exercise equipment of claim 1, wherein the magnet (532) surrounds the piston rod (534), and the conductive member (533) is connected to an inner wall of the cylinder case (531).
     
    4. The exercise equipment of claim 1, wherein the piston rod (534) is a screw rod, ball screw rod or twist screw rod.
     
    5. The exercise equipment of claim 1, further comprising:
    a resistance adjusting device for changing a relative position between the magnet (632) and the conductive member (633).
     
    6. The exercise equipment of claim 5, wherein the resistance adjusting device comprises:

    a rotating base (636), wherein the conductive member (633) is connected to the inner wall of the cylinder case (631) via the rotating base (636); and

    an adjusting cover (637) rotatbly connected to the cylinder case (631) and linked up with the rotating base (636).


     
    7. The exercise equipment of claim 1, wherein the piston rod (834) of the magnetic resistance device (830) is a ball screw rod, and the magnetic resistance device (830) further comprises:

    a telescopic tube (836) movably inserted into the cylinder case (831); and

    a ball screw cap (837) located in the telescopic tube (836) and is inserted by the piston rod (834) for rotating the piston rod (834).


     
    8. The exercise equipment of claim 1, wherein the piston rod (934) is a gear rack, and the magnetic resistance device (930) further comprises:
    a gear (937), wherein the gear (937) is rotated by the piston rod (934) and links up with the conductive member (933).
     
    9. The exercise equipment of claim 1, wherein the piston rod (1034) of the magnetic resistance device is a twist screw rod, and the magnetic resistance device (1030) further comprises:

    a telescopic tube (1036) movably inserted into the cylinder case (1031); and

    a twist screw cap (1037) located in the telescopic tube (1036) and is inserted by the piston rod (1034) for rotating the piston rod (1034).


     


    Ansprüche

    1. Trainingsgerät, umfassend:

    eine Basis (510),

    eine Betätigungsvorrichtung (520), die beweglich an der Basis (510) angeordnet ist, und

    wenigstens eine magnetische Widerstandsvorrichtung (530), die mit der Betätigungsvorrichtung (520) und der Basis (510) verbunden ist, wobei die magnetische Widerstandsvorrichtung (530) zur Bereitstellung eines magnetischen Widerstands entsprechend einer Betätigung der Betätigungsvorrichtung (520) dient, wobei die magnetische Widerstandsvorrichtung (530) umfasst:

    ein Zylindergehäuse (531), das an der Basis (510) angeordnet ist, und

    eine Magnetwiderstandbauteilgruppe, welche umfasst:

    wenigstens einen Magneten (532) und

    wenigstens ein leitfähiges Element (533), welches zu dem Magneten (532) benachbart ist und aus Kupfer, Silber oder Aluminium gefertigt ist,

    dadurch gekennzeichnet, dass

    sich die Magnetwiderstandbauteilgruppe in dem Zylindergehäuse (531) befindet und

    die magnetische Widerstandsvorrichtung (530) ferner eine Kolbenstange (534) umfasst, wobei ein Ende der Kolbenstange (534) mit der Betätigungsvorrichtung (520) gekoppelt ist, um eine Bewegung zwischen dem Magneten (532) und dem leitfähigen Element (533) zu schaffen, sodass der magnetische Widerstand erzeugt wird,


     
    2. Trainingsgerät nach Anspruch 1, bei welchem die Betätigungsvorrichtung (520) umfasst:

    zwei Betätigungselemente (521), die schwenkbar mit der Basis verbunden sind, und

    zwei Pedale (522), die entsprechend an den Betätigungselementen angeordnet sind.


     
    3. Trainingsgerät nach Anspruch 1, bei welchem der Magnet (532) die Kolbenstange (534) umgibt, wobei das leitfähige Element (533) mit einer Innenwand des Zylindergehäuses (531) verbunden ist.
     
    4. Trainingsgerät nach Anspruch 1, bei welchem die Kolbenstange (534) eine Schraubenstange, eine Kugelgewindestange oder eine Drallgewindestange ist.
     
    5. Trainingsgerät nach Anspruch 1, ferner umfassend:
    eine Widerstandseinstellvorrichtung zur Änderung einer relativen Position zwischen dem Magnet (632) und dem leitfähigen Element (633).
     
    6. Trainingsgerät nach Anspruch 5, bei welchem die Widerstandseinstellvorrichtung umfasst:

    eine Drehbasis (636), bei welcher das leitfähige Element (633) über die Drehbasis (636) mit der Innenwand des Zylindergehäuses (631) verbunden ist, und

    einen Verstelldeckel (637), der drehbar mit dem Zylindergehäuse (631) verbunden ist und mit der Drehbasis (636) gekoppelt ist.


     
    7. Trainingsgerät nach Anspruch 1, bei welchem die Kolbenstange (834) der magnetischen Widerstandsvorrichtung (830) eine Kugelgewindestange ist, wobei die magnetische Widerstandsvorrichtung (830) ferner umfasst:

    ein Teleskoprohr (836), welches beweglich in das Zylindergehäuse (831) eingesetzt ist, und

    eine Kugelgewindekappe (837), die sich in dem Teleskoprohr (836) befindet und von der Kolbenstange (834) durchsetzt ist, um die Kolbenstange (834) zu drehen.


     
    8. Trainingsgerät nach Anspruch 1, bei welchem die Kolbenstange (934) eine Zahnstange ist, wobei die magnetische Widerstandsvorrichtung (930) ferner umfasst:
    ein Zahnrad (937), bei welchem das Zahnrad (937) durch die Kolbenstange (934) gedreht wird und mit dem leitfähigen Element (933) gekoppelt ist.
     
    9. Trainingsgerät nach Anspruch 1, bei welchem die Kolbenstange (1034) der magnetischen Widerstandsvorrichtung eine Drallgewindestange ist, wobei die magnetische Widerstandsvorrichtung (1030) ferner umfasst:

    ein Teleskoprohr (1036), welches beweglich in das Zylindergehäuse (1031) eingesetzt ist, und

    eine Drallgewindekappe (1037), die sich in dem Teleskoprohr (1036) befindet und von der Kolbenstange (1034) durchsetzt ist, um die Kolbenstange (1034) zu drehen.


     


    Revendications

    1. Equipement d'exercice, comprenant:

    une base (510);

    un dispositif d'actionnement (520) disposé de manière mobile sur la base (510); et

    au moins un dispositif de résistance magnétique (530) relié au dispositif d'actionnement (520) et à la base (510), dans lequel le dispositif de résistance magnétique (530) est destiné à fournir une résistance magnétique en fonction d'un actionnement du dispositif d'actionnement (520), dans lequel le dispositif de résistance magnétique (530) comprend:

    un carter cylindrique (531) disposé sur la base (510); et

    un ensemble composant de résistance magnétique comprenant:

    au moins un aimant (532); et

    au moins un élément conducteur (533) adjacent à l'aimant (532) et étant constitué de cuivre, d'argent ou d'aluminium;

    caractérisé en ce que

    l'ensemble composant de résistance magnétique est situé dans le carter cylindrique (531), et

    le dispositif de résistance magnétique (530) comprend en outre une tige de piston (534), dans lequel une extrémité de la tige de piston (534) est associée au dispositif d'actionnement (520) pour fournir un mouvement entre l'aimant (532) et l'élément conducteur (533), de sorte que la résistance magnétique est générée.


     
    2. Equipement d'exercice selon la revendication 1, dans lequel le dispositif d'actionnement (520) comprend:

    deux éléments d'actionnement (521) reliés de manière pivotante à la base; et

    deux pédales (522) disposées respectivement sur les éléments d'actionnement.


     
    3. Equipement d'exercice selon la revendication 1, dans lequel l'aimant (532) entoure la tige de piston (534), et l'élément conducteur (533) est relié à une paroi interne du carter cylindrique (531).
     
    4. Equipement d'exercice selon la revendication 1, dans lequel la tige de piston (534) est une tige de vis, une tige de vis à billes ou une tige de vis torsadée.
     
    5. Equipement d'exercice selon la revendication 1, comprenant en outre:
    un dispositif de réglage de résistance pour modifier une position relative entre l'aimant (632) et l'élément conducteur (633).
     
    6. Equipement d'exercice selon la revendication 5, dans lequel le dispositif de réglage de résistance comprend:

    une base rotative (636), dans lequel l'élément conducteur (633) est relié à la paroi interne du carter cylindrique (631) via la base rotative (636); et

    un capot de réglage (637) relié de manière rotative au carter cylindrique (631) et associé à la base rotative (636).


     
    7. Equipement d'exercice selon la revendication 1, dans lequel la tige de piston (834) du dispositif de résistance magnétique (830) est une tige de vis à billes, et le dispositif de résistance magnétique (830) comprend en outre:

    un tube télescopique (836) inséré de manière mobile dans le carter cylindrique (831); et

    une tête de vis à billes (837) située dans le tube télescopique (836) et pénétrée par la tige de piston (834) pour faire tourner la tige de piston (834).


     
    8. Equipement d'exercice selon la revendication 1, dans lequel la tige de piston (934) est une crémaillère, et le dispositif de résistance magnétique (930) comprend en outre:
    un engrenage (937), dans lequel l'engrenage (937) est tourné par la tige de piston (934) et est associé à l'élément conducteur (933).
     
    9. Equipement d'exercice selon la revendication 1, dans lequel la tige de piston (1034) du dispositif de résistance magnétique est une tige de vis torsadée, et le dispositif de résistance magnétique (1030) comprend en outre:

    un tube télescopique (1036) inséré de manière mobile dans le carter cylindrique (1031); et

    une tête de vis torsadée (1037) située dans le tube télescopique (1036) et pénétrée par la tige de piston (1034) pour faire tourner la tige de piston (1034).


     




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    Cited references

    REFERENCES CITED IN THE DESCRIPTION



    This list of references cited by the applicant is for the reader's convenience only. It does not form part of the European patent document. Even though great care has been taken in compiling the references, errors or omissions cannot be excluded and the EPO disclaims all liability in this regard.

    Patent documents cited in the description