The present invention relates to a gymnastic machine. In particular, the present invention relates to a gymnastic machine effectively usable for simulating the skating movement.
In the field of gymnastic machines for cardiovascular training there are well-known gymnastic machines provided with a load group comprising a regulating unit of an electromagnetic nature. Among these machines stationary bikes, treadmills, steppers and so-called cross trainers, i.e. machines provided with footrests movable along elliptic trajectories, are well-known. In the case of the treadmills, the performed exercise directly involves also the use of the arms, which generally perform an oscillating movement in a substantially vertical plane, wherein the forearms swing forward and backward accompanying the movement of the lower limbs. In the other cases, movement of the arms may or may not be provided for but, in any case, for instance in stationary bikes and cross trainers, this movement can take place against the resistance of a load group, for example through the installation of a pair of levers pivoted to the frame, each of which is provided with a handgrip, is connected to the load group by means of a plurality of cylindrical turning pairs, and is movable along a plane that is vertical and thus parallel to the plane on which the pedals move. A solution of this kind is described in the U.S. Pat. No. 6,752,744 by the American firm Precor, but can be verified by observing the machine called “Cross Trainer” of the American firm Ultratrek.
Naturally, the use of the arms in association with the use of the lower limbs allows training to be made collectively more efficient from the muscular point of view and allows better distribution of muscle strain between the upper part and the lower part of the body, thus allowing a noteworthy increase in the percentage of exercises completed according to the provided exercise tables even in conditions of fatigue of one of the two articular regions, given that the part suffering the most from fatigue can be helped by the part with more muscular power.
The movement that can be provided on the simulators is a curvilinear movement in space, whose radius of curvature changes when there is a variation of each angular position of the lever carrying the respective footrest; therefore, cardiovascular training of the so-called “total body” type cannot be achieved by modifying the skating simulators similarly to what is known for stationary bikes, steppers and cross trainers, due to the fact that the types of trajectories are completely different.
In view of the above description, the problem of allowing, in a simple manner and with limited costs, performance of a movement of the upper limbs against the resistance of a single load group in skating simulators is currently unsolved and represents an interesting challenge for the applicant, in order to facilitate performance of the exercises and to make these more complete from the point of view of muscular development. In view of the above description, it would be desirable to have available a gymnastic machine for simulating the skating movement which, in addition to enabling to limit and possibly to overcome the typical drawbacks of the art illustrated above in a simple and cost-effective manner, could define a new standard for training with combined movements of the parts.
The present invention relates to a gymnastic machine. In particular, the present invention relates to a gymnastic machine effectively usable for simulating the skating movement.
The object of the present invention is to provide a gymnastic machine that allows the disadvantages described above to be solved, and which is suitable to satisfy a plurality of requirements that to date have still not been addressed, and therefore, suitable to represent a new and original source of economic interest and capable of modifying the current market of gymnastic implements for gymnasiums or for home use.
According to the present invention, a gymnastic machine is provided, whose main characteristics are described in at least one of the appended claims.
Further characteristics and advantages of the gymnastic machine according to the present invention will be more apparent from the description below, set forth with reference to the accompanying drawings, which illustrate at least one non-limiting example of embodiment, in which identical or corresponding parts of the device are identified by the same reference numbers. In particular:
In
Furthermore, the exercise station 30 comprises a second functional group 60 provided with a pair of levers 61, each of which is pivoted at the front to the frame 10 in correspondence of a substantially horizontal common axis 66 by means of a cylindrical pair 67 and, as shall become more readily apparent from the description below, is associated with a respective footrest 33. Each lever 61 presents at least a handgrip 62 positioned on the upper part in
The machine 1 further comprises a transmission device 70 suitable to determine the mechanical connection of each handgrip 62 with the respective footrest 33, and therefore with the same load unit 20, for performing an exercise for training the upper limbs in combination with an exercise for training the lower limbs actuatable through simulation of the skating movement.
The transmission device 70 comprises a lever 73 for connecting each side of the machine 1 with respect to the longitudinal median plane M, and each lever 73 is substantially rectilinear and positioned between the corresponding footrest 33 and the lever 61 in order to constrain these latter to be operatable in phase with respect to the frame 10. This means that, in use, when a user actuates a footrest 33 along the descending path, the corresponding lever 61, positioned at the same side with respect to the median plane M, as shown in
The connection between each footrest 33 and the respective lever 73 is mediated by the respective lever 36/37, to which the lever 73 is effectively coupled, as shall become more readily apparent from the description below, in correspondence of a bracket 38. In this regard, as shown in
Each lever 73 can present longitudinal extension which is telescopically adjustable and can be fixed on a given length, for example by means of a transverse dowel, known and therefore not shown, so as to allow regulation as desired of the starting position of the first ends 64, and therefore of the position of the limits of the oscillating movement of each handgrip 62. This allows different muscle regions of the upper limbs to be recruited according to the needs of the user.
In view of the above description, operation of the machine 1 described above is completely understood and requires no further explanations. However, it may be advisable to specify that by means of the machine 1, and in particular by means of the connection between the first and the second functional group 31 and 60 provided through the transmission device 70, it is possible to perform training of the “total body” type using only one load unit, i.e. the unit 20, and therefore with very limited modifications to any skating simulator.
Finally, it is apparent that modifications and variants can be made to the gymnastic machine 1 described and illustrated herein without however departing from the protective scope of the present invention.
For example, with particular reference to
The machine 100 comprises a return mechanism 555 which comprises a shaft 557 pivoted to the frame 110 on an axis 114 and carries, keyed, a pair of wheels 556, better described hereafter. It should be noted that the axis 114, and therefore the shaft 557, is positioned between the pivot axes of the levers 610 and the footrests 330. The mechanism 555 comprises two cranks 558 keyed on the shaft 557 in an end position, each of which is connected to the respective lever 360 or 370 by means of a connecting rod 559. Furthermore, a crank 560 is associated with each crank 558 in an angularly fixed manner; this crank 560 is carried by the shaft 557 and belongs to the transmission device 700. This latter further comprises a pair of further connecting rods 561, each of which is positioned between the corresponding crank 560 and a lever 610 positioned at the same side of the plane M. Each connecting rod 561 is coupled in an articulated manner to a free end of a corresponding crank 560 and to a free end 640 of the corresponding lever 610.
In view of the above description, it is easy to understand that the use of the return mechanism 555 allows the right and the left part of the machine 1 to be connected to each other, and, in particular, to provide this connection in a rigid manner. Furthermore, the presence of the device 700 allows connection of the footrests 330 and the levers 610, and thus allows a reduction in the strain necessary to perform the return path towards the raised position of the footrests 330, which is more onerous for less experienced or trained users, or for users who are not familiar with the skating movement.
With reference to
It should be noted that the wheels 556 are connected to the respective freewheel 540 by means of a belt 541, and that the two belts 541 are mechanically coupled to the shaft 511 at opposite sides to the driven wheel 510, in order to transmit twisting movements of the same degree to the shaft 557, even if acting at opposite sides with respect to the driven wheel 510. In this regard, as shown in
It should be noted that the two levers 610 are pivoted to the frame by means of known turning pairs, which constrain the two levers 610 to oscillate on axes 611 and 612 which cross each other at a point positioned at the side of the footrests 330, in such a way that it is possible to act on these levers 610 acting in a convergent manner and following a scheme, according to which the user's hands approach the plane M as the distance from the user's chest increases, and vice versa.
This allows to respect a physiological aptitude and, therefore, to fully exploit the thrust action exercised by the arms and their return towards a rest position. Therefore, the presence in combination of the freewheels 540 and of the return mechanism 555 allows to mechanically decouple the shaft 751 of the brake 750 and the shaft 557 of the cranks 558, and thus to combine the possibility of coupling the right and the left parts of the machine 100 in a rigid manner with the possibility of varying at will the stride width; in this way, it is possible to define the machine 100 as a “variable stride width machine”. Moreover, this arrangement allows use of the machine 100 to be made truly intuitive and safe, with the result of increasing the number of prospective users of the machine 1 described above.
Moreover, the use of the machine 100 can be further facilitated by providing the machine 100 with an accumulator device 800 for accumulating kinetic energy. In
In view of the above description, the mechanical connection of the levers 610 by means of the accumulator device 800 for accumulating kinetic energy positioned on the axis 111 of the brake 750 doubled by the rigid connection between the levers 610 established by the return mechanism 555′ allows to achieve the result of mechanically connecting the footrests 330 in a rigid manner and of accumulating motion energy during the descending path of the footrests 330 sufficient to recover energy during motion which helps the user during the ascending phase of the footrests 330.
It should be specified that in
Number | Date | Country | Kind |
---|---|---|---|
RA2006A000072 | Nov 2006 | IT | national |
Number | Name | Date | Kind |
---|---|---|---|
4781372 | McCormack | Nov 1988 | A |
4811941 | Elo | Mar 1989 | A |
4869496 | Colombo | Sep 1989 | A |
4915373 | Walker | Apr 1990 | A |
5692995 | Alvarez et al. | Dec 1997 | A |
5911650 | Cox | Jun 1999 | A |
6231484 | Gordon | May 2001 | B1 |
6238321 | Arnold et al. | May 2001 | B1 |
6277055 | Birrell et al. | Aug 2001 | B1 |
6849032 | Chu | Feb 2005 | B2 |
7115073 | Nizamuddin | Oct 2006 | B2 |
7244217 | Rodgers, Jr. | Jul 2007 | B2 |
7303509 | Schroder | Dec 2007 | B2 |
7338414 | Hsiung | Mar 2008 | B1 |
7402126 | Chang | Jul 2008 | B2 |
20050245357 | Horvath | Nov 2005 | A1 |
20060293153 | Porth et al. | Dec 2006 | A1 |
20070042871 | Wu et al. | Feb 2007 | A1 |
20070238582 | Lee | Oct 2007 | A1 |
Number | Date | Country |
---|---|---|
1598095 | Nov 2005 | EP |
Number | Date | Country | |
---|---|---|---|
20080132385 A1 | Jun 2008 | US |