JP2017217091A - Exercise machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an exercise machine in which preparation for exercise can be made while a rotation body is in a stationary state.SOLUTION: An exercise machine includes a rotation body that rotates by a rotation operation by human power, a circular electrical conductor that rotates interlocking with the rotation body, magnets disposed facing the surface of the electrical conductor for generating eddy current in the rotating electrical conductor, a movable holding part for holding the magnets and operating so as to change a distance between the magnets and the electrical conductor, and an exercise inhibiting part that acts on a drive part including the rotation body and the electrical conductor to maintain a stationary state of the drive part.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an exercise machine.

  2. Description of the Related Art Conventionally, fitness bikes that improve endurance and eliminate lack of exercise by rotating a pedal are known as exercise machines (for example, Patent Document 1). As fitness bikes, there are known an upright type that can be used in the same manner as a bicycle, a recumbent type with a pedal on the front side, and a mini bike type that does not have a handle and saddle. The mini bike type fitness bike can be used in a sitting position or a supine position, and is an exercise machine suitable for an elderly person whose physical strength is lowered.

  Such fitness bikes ensure stable rotation by utilizing the inertial force of the flywheel that is linked to the rotational movement of the pedal. Further, a load device that provides a resistance force to the rotation of the flywheel is provided, and is configured to be able to change the load for the rotational motion operation.

JP 2000-140153 A

  In the conventional exercise machine, although a load can be applied to the rotation of the pedal, the stationary state where the pedal does not rotate cannot be maintained. For this reason, when the user puts his foot on the pedal and gets on the exercise machine, the pedal may rotate and the balance may be lost. In addition, the present inventors have developed an exercise machine that can perform exercise with higher load by improving the mini bike type used in the sitting position or the supine position and using it in an upright state. proceeding. Since the minibike-type exercise machine does not include a handle and a saddle, the balance is more easily lost when the user gets on.

  It is an object of some aspects of the present invention to provide an exercise machine that is ready for exercise (eg, riding on an exercise machine), that is, with the pedal stationary.

  Another object of another aspect of the present invention is to provide an exercise machine that makes it possible to achieve the effects described in the embodiments described later.

  In order to solve the above-described problems, one embodiment of the present invention is directed to a rotating body that is rotated by a rotating operation by human power, a circular conductor that rotates in conjunction with the rotating body, and a surface of the conductor. A magnet that generates an eddy current in the arranged and rotating conductor part, a movable holding part that holds the magnet and operates to change a distance between the magnet and the conductor part, the rotating body, and the conductor part An exercise machine comprising: an exercise preventing unit that acts on the drive unit including the movement preventing unit to maintain the stationary state of the drive unit.

It is the schematic of the exercise machine of 1st Embodiment, and shows a high load state. It is the partial schematic diagram of the exercise machine of a 1st embodiment, and shows a low load state. It is the partial schematic diagram of the exercise machine of a 1st embodiment, and shows a resting state. The partial schematic of the exercise machine of 2nd Embodiment is shown. The partial schematic diagram of the exercise machine of a 3rd embodiment is shown.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
In the drawings used in the following description, for the purpose of emphasizing the feature portion, the feature portion may be shown in an enlarged manner for convenience, and the dimensional ratios of the respective constituent elements are not always the same as in practice. Absent. In addition, for the same purpose, portions that are not characteristic may be omitted from illustration.

[First Embodiment]
FIG. 1 is a schematic diagram of an exercise machine 1 according to the first embodiment.
The exercise machine 1 includes a housing 3, a pair of step tables 12, a large pulley (an example of a rotating body) 10 that rotates by rotating the step table 12, and a flywheel that rotates in conjunction with the rotation of the large pulley 10. (An example of a conductor part) 20 and the load control part 2 which provides resistance with respect to rotation of the flywheel 20 are provided.

  The pair of step bases 12 are connected to the rotating shaft 11 of the large pulley 10 via cranks 13 respectively. The pair of step bases 12 are configured such that the user M can stand on his / her own with one foot on the other.

  The large pulley 10 is supported so as to be rotatable about the rotation shaft 11. The rotation shaft 11 of the large pulley 10 extends along the left-right direction of the user M. The large pulley 10 is rotated by a rotating operation by human power through the step base 12. A belt 14 is wound around the outer periphery 10 a of the large pulley 10.

  The flywheel 20 is composed of a conductor. Examples of the material of the flywheel 20 include steels including stainless steel and aluminum alloys. The flywheel 20 has a disk shape. Note that the flywheel 20 is not limited to a disk shape as long as a portion facing a permanent magnet 30 described later is circular, and may be an annular shape as an example.

  A small pulley 21 is fixed to the flywheel 20. The flywheel 20 and the small pulley 21 are supported so as to be rotatable about a rotation shaft 22. The rotating shaft 22 extends along the left-right direction of the user M. The flywheel 20 and the small pulley 21 rotate integrally around the rotation shaft 22. A belt 14 is wound around the outer periphery of the small pulley 21.

  The belt 14 is tensioned and wound around the large pulley 10 and the small pulley 21, and transmits the rotation of the large pulley 10 to the small pulley 21. Thereby, the rotation operation of the step base 12 by the user M is transmitted to the flywheel 20 and the flywheel 20 is rotated. In addition, since the large pulley 10 and the small pulley 21 are linked via the belt 14, when the rotation of the flywheel 20 is limited by the action of the load control unit 2 described later, the rotation operation of the step base 12 is also limited. Is done.

The load control unit 2 has a function of applying a load to the rotation of the flywheel 20 and a function of preventing the flywheel 20 from rotating and maintaining a stationary state.
The load control unit 2 includes a link (an example of a movable holding unit) 50 that rotates about a fulcrum shaft (an example of a fulcrum) 52, and a plurality (three in this embodiment) of permanent magnets (an example of this embodiment). An example of a magnet) 30 and a rubber material (an example of a movement prevention unit) 40, a lever (an example of an operation unit) 60 for operating the rotation of the link 50 via a wire 61, and the link 50 are urged in one direction. Coil spring (an example of an urging member) 55.

  The link 50 is disposed along the outer peripheral surface (an example of the surface) OF of the flywheel 20. The link 50 includes a holding portion (an example of a holding body) 50a that holds the permanent magnet 30 and the rubber material 40, a bearing portion 50b that is positioned at one end T1 on the lower side of the holding portion 50a, and the other end on the upper side of the holding portion 50a. And a wire fixing portion 50c to which the wire 61 is fixed at T2.

  The holding part 50 a of the link 50 is formed to be curved along a circular shape with respect to the outer peripheral surface OF of the flywheel 20. The radius of curvature of the holding portion 50a is slightly larger than the radius of the outer peripheral surface OF. The holding part 50a has a facing surface S1 that faces the outer peripheral surface OF. A plurality of permanent magnets 30 and a rubber material 40 are fixed to the facing surface S1. The link 50 rotates about the fulcrum shaft 52. Thereby, the permanent magnet 30 and the rubber material 40 fixed to the holding part 50a are close to or separated from the outer peripheral surface OF.

The bearing portion 50 b of the link 50 functions as a bearing for the fulcrum shaft 52 fixed to the housing 3. That is, the bearing portion 50b is rotatably supported by the fulcrum shaft 52.
The wire fixing portion 50c of the link 50 extends linearly from the other end T2 of the holding portion 50a to the side opposite to the fulcrum shaft 52 (upper side in the present embodiment). Further, a fastening portion 50d for fixing the end portion of the wire 61 is provided in the vicinity of the tip of the wire fixing portion 50c.

  A plurality of permanent magnets 30 are arranged in an arc shape so as to be held by the link 50 and face the outer peripheral surface OF of the flywheel 20. The permanent magnet 30 generates an eddy current in the rotating flywheel 20 and causes a load in the rotational movement of the flywheel 20.

  The permanent magnet 30 approaches or separates from the outer peripheral surface OF as the link 50 rotates. The load of the rotational motion of the flywheel 20 by the permanent magnet 30 depends on the distance between the permanent magnet 30 and the flywheel 20. When the permanent magnet 30 is farthest from the outer peripheral surface OF of the flywheel 20 (see FIG. 2), the eddy current generated on the outer peripheral surface OF is minimized, and the load on the rotation of the flywheel 20 is minimized. On the other hand, when the permanent magnet 30 is closest to the outer peripheral surface OF of the flywheel 20 (see FIG. 1), the eddy current generated on the outer peripheral surface OF is maximized and the load on the rotation of the flywheel 20 is maximized.

  The rubber material 40 is held by the link 50 and is disposed so as to face the outer peripheral surface OF of the flywheel 20. The rubber material 40 is formed higher than the permanent magnet 30 with respect to the facing surface S <b> 1 of the link 50. Therefore, the distance between the rubber material 40 and the outer peripheral surface OF is smaller than the distance between the permanent magnet 30 and the outer peripheral surface OF. As the link 50 rotates, the rubber material 40 comes into contact with the outer peripheral surface OF of the flywheel 20 that is stationary, and maintains the stationary state of the flywheel 20 by static frictional force.

  The permanent magnet 30 and the rubber material 40 are held by the holding portion 50 a of the link 50 on one side in the radial direction with respect to the fulcrum shaft 52. Therefore, as the link 50 rotates, the permanent magnet 30 and the rubber material 40 simultaneously approach or separate from the outer peripheral surface OF.

  One end of the coil spring 55 is fixed to the housing 3 in the stretched state, and the other end is fixed to the outer surface S <b> 2 facing the opposite surface S <b> 1 of the link 50. The coil spring 55 biases the link 50 in a direction in which the link 50 is separated from the flywheel 20.

  The lever 60 is formed in a bar shape extending in the vertical direction. The lever 60 is supported by the housing 3 so as to be rotatable about the lower end so as to tilt forward or backward. In the middle of the lever 60 in the vertical direction, a fastening portion 60a for fixing the end portion of the wire 61 is provided.

  The lever 60 is tilted forward or backward by the operation of the user M. The lever 60 is connected (connected) to the link 50 via a wire 61. Since the link 50 is urged to one side (left side in FIG. 1) by the coil spring 55, stress acts on the lever 60 on one side via the wire 61. The rotation shaft of the lever 60 is provided with a ratchet mechanism for resisting this stress.

[Action]
Next, the operation of the exercise machine 1 of this embodiment will be described.
The exercise machine 1 can switch the high load state, the low load state, and the stationary state by operating the link 50 of the load control unit 2 by operating the lever 60.
FIG. 1 shows an exercise machine 1 in which the load control unit 2 is set to a high load state. FIG. 2 is a schematic diagram of the load control unit 2 set to a low load state. FIG. 3 is a schematic diagram showing the load control unit 2 set in a stationary state.

The high load state shown in FIG. 1 is a state in which the rubber material 40 is separated from the outer peripheral surface OF of the flywheel 20 and the permanent magnet 30 faces the outer peripheral surface OF of the flywheel 20 at the first distance d1.
The low load state shown in FIG. 2 is a state in which the rubber material 40 is separated from the outer peripheral surface OF of the flywheel 20 and the permanent magnet 30 faces the outer peripheral surface OF of the flywheel 20 at the second distance d2. The second distance d2 is greater than the first distance d1. Therefore, the eddy current flowing on the surface of the rotating flywheel 20 is smaller in the low load state. Thereby, in a low load state, the rotational load of the flywheel 20 becomes small compared with a high load state.
In the present embodiment, the load adjustment has been described as being performed in two stages. However, a plurality of stages (or no stages) in which the strength of the load changes between a high load state and a low load state are prepared. It may be.

  The stationary state shown in FIG. 3 is a state in which the rubber material 40 is in contact with the outer peripheral surface OF of the flywheel 20 and the rotational movement of the flywheel 20 is blocked by the static friction force. In the stationary state, the rotational movement of the flywheel 20 is blocked, and the rotation operation of the step table 12 is blocked. That is, even if a force is applied to the step table 12, the rotation of the flywheel 20 is prevented, and the step table 12 cannot be rotated.

The stationary state is mainly used when the user M gets on the step board 12. By setting the stationary state, the stationary state of the step base 12 is maintained, so that the user M can get on the exercise machine 1 without breaking the balance.
In the present embodiment, the rubber material 40 that exerts a static friction force on the flywheel 20 is exemplified as a motion blocking portion that maintains the stationary state of the flywheel 20. However, you may use what consists of materials other than rubber | gum as a means to apply a static friction force. Further, the movement preventing unit may be in any form as long as it acts on the driving unit 6 including the large pulley 10 and the flywheel 20 to maintain the stationary state of the driving unit 6. For example, the movement preventing unit may act on the large pulley 10 or the small pulley 21. Moreover, you may employ | adopt as a motion prevention part the stopper mechanism which makes the stationary drive part 6 bite and maintains a stationary state. Here, the drive unit 6 refers to a portion that is provided in a transmission path from the large pulley 10 to the flywheel 20 and operates in conjunction with the large pulley 10. In the present embodiment, the drive unit 6 refers to any one of the large pulley 10, the belt 14, the small pulley 21, and the flywheel 20. The movement preventing unit can maintain the stationary state of the step base 12 connected to the large pulley 10 by maintaining the stationary state of the driving unit 6 that is interlocked with the large pulley 10.

[Summary of First Embodiment]
As described above, the exercise machine 1 according to the present embodiment includes the large pulley 10 (an example of a rotating body), a circular flywheel 20 (an example of a conductor portion), a permanent magnet 30 (an example of a magnet), A link 50 (an example of a movable holding unit) and a rubber member 40 (an example of a motion prevention unit) are provided. The large pulley 10 is rotated by a rotating operation by human power. The flywheel 20 rotates in conjunction with the large pulley 10. The permanent magnet 30 is disposed to face the outer peripheral surface OF (an example of the surface) of the flywheel 20. Thereby, the permanent magnet 30 generates an eddy current in the rotating flywheel 20. The link 50 holds the permanent magnet 30. Further, the link 50 operates so as to change the distance between the permanent magnet 30 and the flywheel 20. The motion preventing unit acts on the driving unit 6 including the large pulley 10 and the flywheel 20 to maintain the stationary state of the driving unit 6. An example of the movement prevention unit is one that maintains a static state by a static friction force.

  According to the present embodiment, the operation of the drive unit 6 of the exercise machine can be limited by maintaining the stationary state of the flywheel 20 with the rubber material 40. The user M can prepare the exercise (ride on the exercise machine) with the exercise machine 1 in a stationary state, and the user M may lose balance due to the unexpected operation of the large pulley 10 and the step base 12. Can be suppressed.

  As conventional exercise machines, there are known an eddy current brake type load control and a friction type load control. Among these, those that perform frictional load control adjust the load against rotation using dynamic friction, for example, by pressing a brake pad against a rotating rotating body. The rubber material 40 (an example of the movement preventing unit) of the present embodiment is intended to fix the step base 12 by acting on the stationary flywheel 20 and maintaining the stationary state, and the operation principle and operation are Completely different.

In the exercise machine 1 according to the present embodiment, the rubber material 40 (an example of an exercise prevention unit) is held by a link 50 (an example of a movable holding unit). Further, the link 50 operates so as to bring the rubber material 40 into contact with the flywheel 20.
In the present embodiment, the permanent magnet 30 and the rubber material 40 are arranged facing the outer peripheral surface OF (an example of the surface) of the flywheel 20. Further, the distance between the permanent magnet 30 and the rubber material 40 and the flywheel 20 changes with the operation of the link 50. Furthermore, a gap is provided between the permanent magnet 30 and the outer peripheral surface OF in a state where the rubber material 40 is in contact with the outer peripheral surface OF of the flywheel 20.

  According to this configuration, the permanent magnet 30 and the rubber material 40 are provided on the link 50. Therefore, the operation of the link 50 can switch the proximity and separation of the permanent magnet 30 with respect to the flywheel 20 and the contact and non-contact of the rubber material 40 with the flywheel 20. That is, it is possible to switch between a stationary state, a high load state, and a low load state with a simple structure.

  The exercise machine 1 according to the present embodiment includes a lever 60 (an example of an operation unit) connected to the link 50. The link 50 operates by operating the lever 60. The exercise machine 1 can be switched between a stationary state, a high load state, and a low load state. The stationary state is a state in which the rubber material 40 contacts the flywheel 20 and prevents the rotational movement of the flywheel 20 (see FIG. 3). The high load state is a state in which the permanent magnet 30 faces the flywheel 20 at the first distance d1 while the rubber material 40 is separated from the flywheel 20 (see FIG. 1). The low load state is a state in which the rubber material 40 is separated from the flywheel 20 and the permanent magnet 30 faces the flywheel 20 at a second distance d2 that is larger than the first distance d1 (see FIG. 2).

  According to this configuration, it is possible to adjust the load (high load state and low load state) and switch the stationary state by a single lever 60. That is, an inexpensive exercise machine 1 can be realized with a simple structure.

  In the exercise machine 1 according to the present embodiment, the link 50 includes a holding unit 50a. The holding part 50 a extends along the outer peripheral surface OF of the flywheel 20. Moreover, the holding | maintenance part 50a rotates centering on the fulcrum axis | shaft 52 (an example of a fulcrum). The permanent magnet 30 is held by the holding portion 50a. The rubber material 40 is held by the holding portion 50 a in the same direction as the permanent magnet 30 with respect to the fulcrum shaft 52.

  According to this configuration, the “low load state”, “high load state”, and “stationary state” are switched in this order along the rotation direction of the link 50. Therefore, the operation direction of the lever 60 and the direction in which the flywheel 20 is difficult to rotate coincide with each other, and the user M can easily understand the operation direction of the lever 60 sensuously.

  The exercise machine 1 according to the present embodiment includes a pair of step bases 12. The pair of step bases 12 are connected to the large pulley 10. The pair of step bases 12 is provided for the user M to stand on his / her feet. The exercise machine 1 causes the rubber member 40 to act, so that the stationary state of the large pulley 10 is maintained even if a force acts on the step base 12.

  According to this configuration, since the user M is self-supporting on the step base 12, it is not necessary to provide the saddle and the handle to the exercise machine 1. The exercise machine 1 can cause the user M to perform effective exercise by using the exercise machine 1 in an independent state on the step base 12.

[Second Embodiment]
FIG. 4 is a schematic diagram of the load control unit 102 and the flywheel 20 of the exercise machine 101 according to the second embodiment.
The exercise machine 101 of the second embodiment is mainly different from the first embodiment in the configuration of the load control unit 102. In addition, about the component of the same aspect as the above-mentioned embodiment, the same code | symbol is attached | subjected and the description is abbreviate | omitted.

  The load control unit 102 includes a link (an example of a movable holding unit) 150 that rotates about a fulcrum shaft 52, a plurality of permanent magnets (an example of a magnet) 30 that are held by the link 150, and first and second rubbers. Materials (an example of a movement prevention unit) 140A and 140B, a lever 60, and a coil spring (not shown, corresponding to the coil spring 55 in FIG. 1) that biases the link 150 in one direction.

  The link 150 is disposed along the outer peripheral surface (an example of the surface) OF of the flywheel 20. The link 150 includes a holding part (an example of a holding body) 150a that holds the permanent magnet 30 and the rubber material 40, a bearing part 150b that functions as a bearing for the fulcrum shaft 52 and is located in the middle in the extending direction of the holding part 150a. A wire fixing portion 150c that is positioned at the end in the extending direction of the holding portion 150a and to which the wire 61 is fixed. The link 150 is operated from the lever 60 via the wire 61 and rotates about the fulcrum shaft 52.

  The holding part 150 a of the link 150 is formed to be curved along the circular shape of the outer peripheral surface OF of the flywheel 20. The permanent magnet 30 and the first and second rubber materials 140A and 140B are fixed to the holding portion 150a facing the outer peripheral surface OF.

  The first rubber material 140A, the three permanent magnets 30, and the second rubber material 140B are arranged in this order in the extending direction of the holding portion 150a. The first rubber material 140A and the three permanent magnets 30 are held by the holding portion 150a on one side in the radial direction with respect to the fulcrum shaft 52. The second rubber material 140B is held by the holding portion 150a on the other side in the radial direction with respect to the fulcrum shaft 52. Therefore, when the first rubber material 140A and the permanent magnet 30 are close to the outer peripheral surface OF, the second rubber material 140B is separated. On the contrary, when the first rubber material 140A and the permanent magnet 30 are separated from the outer peripheral surface OF, the second rubber material 140B comes close.

[Summary of Second Embodiment]
In the exercise machine 101 according to the present embodiment, the link 150 includes a holding unit 150a. The holding part 150 a extends along the outer peripheral surface OF of the flywheel 20. Moreover, the holding | maintenance part 150a rotates centering on the fulcrum axis | shaft 52 (an example of a fulcrum). The permanent magnet 30 is held by the holding portion 150a. The first rubber material 140A and the second rubber material 140B are held by the holding portion 150a in both the same direction and the opposite direction to the permanent magnet 30 with respect to the fulcrum shaft 52.

According to this embodiment, the same effects as those of the above-described embodiment can be obtained.
Further, according to this configuration, the rubber material is used not only when the link 150 is rotated in the direction in which the permanent magnet 30 is brought close, but also when the link 150 is rotated in the direction in which the permanent magnet 30 is separated. The first rubber material 140A or the second rubber material 140B comes into contact with the outer peripheral surface OF of the flywheel 20 to realize a stationary state.

  Further, according to this configuration, the “static state”, “low load state”, “high load state”, and “static state” are switched in this order along the rotation direction of the link 150. That is, the “stationary state” is disposed at both ends of the lever 60 in the operation direction. In the operation of the user M at the time of getting on and off, by operating the lever 60 to one of the end portions, a stationary state can be realized, and the burden of determining the operation direction for the user M who is fatigued by the exercise can be reduced.

[Modification of Second Embodiment]
As a modification of the second embodiment, a configuration in which the first rubber material 140A is omitted may be employed. That is, as a modification, a configuration in which one rubber material 140B is held by the holding portion 150a in the direction opposite to the permanent magnet 30 with respect to the fulcrum shaft 52 can be employed. In this case, the “static state”, “low load state”, and “high load state” are switched in this order along the rotation direction of the link 150. In other words, since the stationary state and the low load state are adjacent to each other when the lever 60 is operated, an exercise machine is provided that makes it easy for the user M to understand the operation procedure when it is recommended to start exercise from the low load state. it can.

[Third Embodiment]
FIG. 5 is a schematic diagram of the load control unit 202 and the flywheel 220 of the exercise machine 201 according to the third embodiment.
The exercise machine 201 of the third embodiment is different in the configuration of the load control unit 202 from the first and second embodiments. More specifically, the load control units 2 and 102 of the first and second embodiments manually operate the proximity and separation of the permanent magnet 30 and the contact and non-contact of the rubber material 40, while the third embodiment. The form load control unit 202 is different in that these are operated by an electric motor. Moreover, the positional relationship with respect to the flywheel 220 differs in the load control part 202 of 3rd Embodiment compared with the load control parts 2 and 102 of 1st and 2nd embodiment.
In addition, about the component of the same aspect as the above-mentioned embodiment, the same code | symbol is attached | subjected and the description is abbreviate | omitted.

In the present embodiment, the flywheel 220 is made of a conductor and has an annular shape. The flywheel 220 is supported so as to be rotatable about a rotation axis (not shown).
The load control unit 202 is disposed inside the flywheel 220 in the radial direction. The load control unit 202 includes a link (an example of a movable holding unit) 250 that rotates about a fulcrum shaft 252, a plurality of permanent magnets (an example of a magnet) 30 that are held by the link 250, and a rubber material (of a motion prevention unit). An example) 40, a cam 270 acting on the link 250, and a coil spring (an example of an urging member) 255 that urges the link 250 to press the cam 270.

  The link 250 is disposed along an inner peripheral surface (an example of a surface) IF of the flywheel 220. The link 250 includes a holding portion (an example of a holding body) 250 a that holds the permanent magnet 30 and the rubber material 40, and a bearing portion 250 b that functions as a bearing for the fulcrum shaft 252 at an end in the extending direction of the holding portion 250 a. Have.

  The holding portion 250a of the link 250 is formed to be curved along the circular shape of the inner peripheral surface 220b of the flywheel 220. The permanent magnet 30 and the rubber material 40 are fixed to the facing surface S21 of the holding portion 250a facing the inner peripheral surface IF. The cam 270 is in contact with the inner surface S22 of the holding portion 250a facing away from the facing surface S21.

  An electric motor (not shown) is connected to the cam 270. The electric motor is operated by an operation unit (not shown) that is electrically connected. The cam 270 rotates eccentrically about the rotation shaft 270a by the driving force of the electric motor. As the cam 270 rotates, the distance between the rotation shaft 270a and the link 250 changes, and the link 250 rotates about the fulcrum shaft 252. Thereby, the proximity and separation of the permanent magnet 30 with respect to the inner peripheral surface 220b of the flywheel 220 and the contact and non-contact of the rubber material 40 are switched, and the stationary state, the high load state, and the low load state are switched.

[Modification]
The embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to the above-described embodiment, and includes a design and the like within a scope not departing from the gist of the present invention. For example, the configurations described in the first to third embodiments can be arbitrarily combined.

For example, in the above-described embodiment, the case where a permanent magnet is used as the magnet is illustrated, but an electromagnet may be used.
Moreover, although the exercise machine which has the step stand for mounting a foot was illustrated in the above-mentioned embodiment, the exercise machine may be rotated by another part such as a hand.
Moreover, in the above-mentioned embodiment, the case where the link which rotates centering on a fulcrum is employ | adopted as a movable holding | maintenance part was illustrated. However, the movable holding part only needs to operate so as to change the distance between the magnet and the conductor part while holding the magnet. As an example, the movable holding portion may change the distance between the magnet and the conductor portion by moving in parallel.
In the above-described embodiment, the case where the coil spring is provided as an example of the biasing member that biases the link in one direction is illustrated. However, the biasing member may have another structure such as a leaf spring. . Further, when the lever and the link are fixed, or when the link is directly operated by the motor, the urging member may not be provided.
Moreover, in the above-mentioned embodiment, although the case where the rubber material and magnet as a movement prevention part were arrange | positioned separately was illustrated, the structure which affixed the rubber material on the surface of a magnet may be employ | adopted.
Further, the motion trajectory of the rotational motion input from the step base 12 is not limited to a circular trajectory, and may be various motion trajectories such as an elliptical trajectory by devising a crank mechanism or the like.

In the first and second embodiments described above, the lever is illustrated as an example of the operation unit. However, a dial type operation unit that operates a link by winding a wire may be employed. Moreover, when operating a link by an electric motor as shown in 3rd Embodiment, the operation part may be a remote control electrically connected with the electric motor. In this case, the connection between the operation unit and the link includes an electrical connection from the operation unit to the motor and a mechanical connection from the motor to the link via the cam. That is, the connection between the operation unit and the link may include both mechanical and electrical connections, and the intention of the user input from the operation unit is reflected in the operation of the link. Any form is possible as long as it can be used.
Moreover, in the above-mentioned embodiment, the flywheel should just be a conductor, and the part which opposes a permanent magnet may not necessarily be a conductor as a whole. That is, the configuration of the flywheel is not limited as long as it can generate an eddy current due to magnetic force on the surface in a rotated state.
In addition, the exercise machine of the above-described embodiment is not only when the user gets on the exercise machine, but also when getting off, the flywheel is made stationary so that the user can balance by the unexpected operation of the step base. Breaking down can be suppressed.
In the above-described embodiment, the exercise machine having no saddle and the handle has been described. However, the above-described configurations can be applied to an exercise machine having a saddle and a handle.
Moreover, the exercise machine of the above-described embodiment can be used for rehabilitation purposes and medical purposes, in addition to the purpose of improving endurance and eliminating lack of exercise.

[Appendix]
From the above description, the present invention is grasped as follows, for example. In order to facilitate understanding of the present invention, reference numerals in the accompanying drawings are appended in parentheses for convenience, but the present invention is not limited to the illustrated embodiment.

  (Supplementary Note 1) An exercise machine (1, 101, 201) according to an aspect of the present invention includes a rotating body (10) that is rotated by a rotating operation by human power, and a circular conductor portion that rotates in conjunction with the rotating body ( 20, 220), a magnet (30) for generating an eddy current in the rotating conductor portion that is disposed to face the surface of the conductor portion (20), and holds the magnet and the magnet and the conductor portion. A movable holding portion (50, 150, 250) that operates to change the distance, and a motion blocking portion that acts on the driving portion (6) including the rotating body and the conductor portion to maintain the stationary state of the driving portion. (40, 140A, 140B).

  According to the configuration of Supplementary Note 1, the operation of the driving unit of the exercise machine can be limited by maintaining the stationary state of the rotating body by the movement preventing unit. As a result, the user can prepare for exercise (ride on the exercise machine) while the exercise machine is in a stationary state, and can prevent the user from losing balance due to an unexpected operation of the rotating body.

  (Additional remark 2) Moreover, one aspect | mode of this invention is the exercise machine (1, 101, 201) of Additional remark 1, Comprising: The said movement prevention part (40,140A, 140B) is the said movable holding | maintenance part (50). 150), and the movable holding portion operates to bring the motion preventing portion into contact with the conductor portions (20, 220).

  According to the configuration of Supplementary Note 2, since the movable holding unit is provided with the magnet and the movement prevention unit, the movable holding unit is operated, so that the magnet is moved toward and away from the conductor unit, and the movement blocking unit with respect to the conductor unit. Can be switched between non-contact and non-contact. That is, it is possible to switch between a stationary state, a high load state, and a low load state with a simple structure.

  (Additional remark 3) Moreover, one aspect | mode of this invention is the exercise machine (1, 101, 201) of Additional remark 2, Comprising: The operation part (60 connected to the said movable holding | maintenance part (50, 150, 250). ), The movable holding portion is operated by the operation of the operation portion, and the movement preventing portion (40, 140A, 140B) contacts the conductor portion (20, 220) to move (rotate) the conductor portion. A stationary state that prevents movement), a high-load state in which the magnet (30) faces the conductor part at a first distance (d1) while the movement preventing part is separated from the conductor part, and the motion preventing part Is switched from a low load state in which the magnet faces the conductor portion at a second distance (d2) larger than the first distance while being separated from the conductor portion.

  According to the configuration of Supplementary Note 3, it is possible to adjust the load and switch the stationary state without providing a plurality of operation units. Thereby, an inexpensive exercise machine with a simple structure can be provided. The connection between the movable holding unit and the operation unit may be a mechanical connection or an electrical connection via a conducting wire (including a connection using radio waves as a transmission means).

  (Additional remark 4) Moreover, 1 aspect of this invention is the exercise machine (1, 101, 201) of Additional remark 2 or Additional remark 3, Comprising: The said movable holding | maintenance part (50, 150, 250) is said conductor part. (20, 220) has a holding body (50a, 150a, 250a) extending around the fulcrum (52, 152, 252) extending along the surface of the (20, 220), and the magnet (30, 230) is the holding body The movement preventing part (40, 140A, 140B, 240) is held by the holding body in one or both of the same direction and the opposite direction to the magnet with respect to the fulcrum. Yes.

  According to the configuration of Supplementary Note 4, by rotating the movable holding portion, it is possible to realize the proximity and separation of the magnet with respect to the conductor portion and the contact and non-contact of the motion blocking portion with a simple structure centered on the fulcrum. In addition, the “static state”, “high load state”, and “low load state” can be arranged in various orders with respect to the operation direction of the movable holding portion, and the degree of freedom in designing the operation configuration can be increased. .

  (Additional remark 5) Moreover, one aspect | mode of this invention is the exercise machine (1, 101, 201) as described in any one of Additional remarks 1-4, Comprising: It connects to the said rotary body (10), and a user ( M) is provided with a pair of step bases (12) for self-supporting on both feet, and the rotation preventing part (40, 140A, 140B) is applied to the step bases even if force is applied to the step bases. The body remains stationary.

  According to the configuration of Supplementary Note 5, the user can perform an effective exercise by using the exercise machine while standing on the step table.

  DESCRIPTION OF SYMBOLS 1,101,201 ... Exercise machine, 6 ... Drive part, 10 ... Large pulley (rotary body), 12 ... Step stand, 20 ... Flywheel (conductor part), 30 ... Permanent magnet (magnet), 40, 140A, 14B ... Rubber material (motion blocking part), 50, 150, 250 ... Link (movable holding part), 50a, 150a, 250a ... Holding part (holding body), 52 ... Furdle shaft (fulcrum), 60 ... Lever (operating part) 220b ... inner peripheral surface (surface), d1 ... first distance, d2 ... second distance, M ... user, OF ... outer peripheral surface (surface), IF ... inner peripheral surface (surface)

Claims (5)

A rotating body that is rotated by a rotating operation by human power;
A circular conductor that rotates in conjunction with the rotating body;
A magnet that creates an eddy current in the rotating conductor portion that is disposed facing the surface of the conductor portion;
A movable holding portion that holds the magnet and operates to change a distance between the magnet and the conductor portion;
A motion preventing unit that acts on a driving unit including the rotating body and the conductor unit to maintain a stationary state of the driving unit;
Comprising an exercise machine. The movement preventing unit is held by the movable holding unit,
The movable holding portion operates to bring the movement preventing portion into contact with the conductor portion.
The exercise machine according to claim 1. An operation unit connected to the movable holding unit;
The movable holding portion is operated by the operation of the operation portion,
A stationary state in which the movement preventing portion contacts the conductor portion and prevents the movement of the conductor portion;
A high load state in which the magnet is opposed to the conductor portion at a first distance while the movement preventing portion is spaced apart from the conductor portion;
A low load state in which the magnet is opposed to the conductor part at a second distance larger than the first distance while the movement preventing part is separated from the conductor part;
The exercise machine according to claim 2. The movable holding portion has a holding body that extends along the surface of the conductor portion and rotates around a fulcrum.
The magnet is held by the holding body,
4. The exercise machine according to claim 2, wherein the movement preventing unit is held by the holding body in one or both of the same direction and the opposite direction to the magnet with respect to the fulcrum. Connected to the rotating body, comprising a pair of step bases for the user to stand on his / her feet,
The exercise machine according to any one of claims 1 to 4, wherein the stationary state of the rotating body is maintained even when a force is applied to the step base by applying the movement prevention unit.

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