US20040033868A1

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Info

Publication number: US20040033868A1
Application number: US10/613,037
Authority: US
Inventors: Willem Van Straaten
Original assignee: Greenhouse International LLC
Current assignee: Greenhouse International LLC
Priority date: 2002-07-03
Filing date: 2003-07-02
Publication date: 2004-02-19
Also published as: AU2003256443A1; CN1708333A; WO2004004842A1

Abstract

An exercise machine which includes a base upon which a user stands alongside an upwardly extending support. A handle, mounted to a lever rotatably fixed to the support, extends over the base so that the user can grip the handle with both hands and rotate the handle along a circular loop, alternately bending at the knees and then moving to an upright position, with arms extended, against a variable resistance force which is generated by a flywheel connected via a drive mechanism to the lever.

Description

BACKGROUND OF THE INVENTION

1. Field of the Invention[0001]

This invention relates to exercise machines, and in particular to an exercise machine that provides continuous load exerting resistance for the user.[0002]

2. Prior Art[0003]

Exercise machines that utilize bicycle like motion for hands and feet are well known in the art. Such machines suffer the drawback that the action is pedal-like in that one arm pushes while the other pulls and vice versa. This action does not provide continuous resistance for each of the pushing and pulling actions, and as such results in an undesirable exercise regiment.[0004]

SUMMARY OF THE INVENTION

The invention provides an exercise machine which includes a support structure, a resistance assembly which is connected to the support structure, a drive member with an output point from which force is applied to the resistance assembly and an input point which is spaced from the output point by a distance L, and at least one handle which acts on the drive member at the input point and which a user can engage and move in a continuous, load-exerting manner, against a resistance force which is generated by the resistance assembly.[0005]

“Continuous, load-exerting” means that the movement of the handle is such that at all times the user is capable of exerting force on the handle to move the drive member against the resistance force. This is to be contrasted with a bicycle-type movement which is encountered in a machine of the type which has support structure with outwardly extending cranked handles on opposed sides of the structure which are moved in alternating or reciprocating movement by a user. With this type of machine the design is such that the user alternately pushes with one arm while pulling with the other arm, and vice versa.[0006]

The machine may have one handle with which one hand of user is engageable. Alternatively the handle may be such that two hands of the user are engageable therewith. In another variation the machine has two handles with which two hands of the user are respectively engageable.[0007]

In a preferred form of the invention the user's arms act in unison on the handle or handles, against the resistance force.[0008]

The expression “acting in unison” is intended to include a movement of the user's arms, whereby the user's arms move substantially in the same way and at the same time as each other. Thus both arms act against the resistance force at the same time. This is to be contrasted with the type of movement, encountered for example on the bicycle-type machine referred to, in which the user's arms move with a pedal-type motion in alternating fashion with one arm pulling and the other arm pushing, and vice versa.[0009]

The input point, when moved by the handle, may move along a path which may form a closed loop of any appropriate shape or which may be variable dynamically ie. as the user works on the handle. It is preferred however that the path of movement is defined and forms a closed loop of circular shape.[0010]

The path of movement of the input point preferably lies in a substantially vertical plane. It is possible though for the path of movement to lie in a substantially horizontally plane, or in an inclined plane, or for the path of movement to be non-planar. For example, if the input point moves laterally relative to the support structure, which may be upwardly extending, then the path of movement, even if it forms a closed loop may not lie in a plane but could follow a convoluted three-dimension path.[0011]

As indicated though it is preferred for the path of movement to lie in a vertical plane for this allows the user to stand on one side of, and adjacent, the plane, away from the support structure. This feature makes it possible for the user to move fully and freely, and obtain maximum benefit from the machine for many parts of the body.[0012]

To enable the user's arms to act in unison on the handle, the exercise machine must be dimensioned and structured so that no part thereof interferes with the body of the user. To achieve this objective the support structure preferably extends upwardly and the handle is on one side of the support structure only.[0013]

The support structure may include a base which is attachable to the floor to stabilise the exercise machine during use thereof.[0014]

In an alternative arrangement, the support structure includes formations whereby the support structure is attachable to a wall to stabilise the exercise machine during use thereof.[0015]

In a preferred embodiment however the exercise machine includes a base which is attached to a lower end of the support structure and which provides a platform upon which the user stands so that the user's mass stabilises the exercise machine during use thereof.[0016]

The length of the drive member between the input point and the output point may be adjustable to vary the distance L. The drive member may be adjustable against a biasing element such as a piston and cylinder arrangement, a spring, an elastic member such as a rubber band or the like, a worm-type device, and so on. The use of a biasing element which may, itself, be adjustable to provide a variable biasing force, enables the input point to move along a path of variable shape. It is possible to make use of control means, eg. an automatically controlled actuator or motor to adjust the length of the drive member, to provide a controlled variation in operating characteristics of the machine.[0017]

On the other hand the drive member may be adjustable according to requirement to set the distance L at a defined length. A releasable fastener, which acts on the drive member once it has been adjusted, may be used to prevent the distance L from varying during use of the exercise machine.[0018]

The drive member may be rotatable by the handle about the output point.[0019]

The handle may take on a plurality of different forms. In one example of the invention the handle includes grips for the user's hands, the grips being positioned so that the hands, when engaged with the grips, extend around a common axis which is transverse to the path of movement of the input point. With this form of the invention the grips are preferably positioned side by side and the handle may, for example, comprise an elongate shaft of sufficient length to ensure that portions of the shaft which are adjacent each other define grips for the user's hands.[0020]

The shaft, which defines the handle, may extend from the drive member at the input point and may be rotatable about an axis which is centered on the input point. It is also possible though, alternatively or in addition, to provide rotatable grips on the shaft so that the grips rotate about the shaft during movement of the drive member by a user.[0021]

In a different form of the invention, the handle includes grips for the user's hands which are positioned on respective opposed sides of an input axis which is transverse to the path of movement of the input point and which extends through the input point. This arrangement allows the user to face a plane in which the input point is moved during use of the exercise machine ie. in which the closed loop lies. With this arrangement the user effectively turns through 90° compared to the position which the user occupies with the first mentioned handle arrangement.[0022]

With the latter handle arrangement the user's arms are again used in unison but with a circular type motion which is transverse to, and in front of, the user's body during use of the exercise machine.[0023]

Different handles may be provided for a single machine and a user may select a handle type, as required, for different types of exercises.[0024]

The handles may allow for the orientation of the grips, relative to the input axis, to be varied in use. This feature reduces the strain which could otherwise be placed on a user's hands and arms during use ie. while causing the input point to rotate, along a path of movement, about the output point. For example, the handle, or the grips, may be connected to the input point through a universal joint, a ball joint, a spring or rubber connector, or any similar device which allows relative pivotal movement between the grips and the input point, but which still allows a drive force to be applied from the grips to the input point.[0025]

The path may have a highest point which is a distance X above a ground reference level on which the user stands and a lowest point which is a distance Y above the ground reference level and wherein X ≧2Y. By adjusting the distance it is possible to make X substantially greater than 2Y.[0026]

By adjusting the ratio of X to Y, the degree to which a user must bend and extend upwardly when moving the handle so that the input point moves along the path, can be significantly varied.[0027]

The support structure, as indicated, can take on a plurality of different forms. However to enable the support structure to be provided in a manner which can be put into a compact mode for storage and transport purposes, it is preferable for the support structure to have at least two upwardly extending inclined supports with the resistance assembly being mounted to the supports, preferably to upper ends thereof.[0028]

Use may be made of a base which interconnects lower ends of the supports and which forms a platform upon which the user stands.[0029]

The supports may be pivotally movable towards each other for storage and transport purposes, and away from each other to place the machine in an operative mode. The base may include a plurality of pivotally interconnected panels which are moved in a corresponding way in unison with the supports.[0030]

The output point may be near the upper ends of the supports and the resistance assembly may include a flywheel which is rotatable about an axis which extends through the output point. Alternatively the exercise machine may include a drive arrangement which is connected to the output point and which transfers motion to the flywheel. The drive arrangement may include a gearbox or gear train, a system of belts and pulleys, or any similar drive transferring system which causes the rotational speed of the flywheel to be related in a desired ratio to the rotational speed of the output point. This increases the force which is generated by the resistance assembly and against which the user acts.[0031]

In a preferred example of the invention, the path of movement of the input point is a circle and the drive arrangement is such that the ratio of the rotational speed of the flywheel to the rotational speed of the output point is greater than 20. It has been found through experimentation and trial and error that this ratio and higher values, eg 25, are particularly effective in that these ratios enable the flywheel to have a relatively small mass (e.g., of the order of 5 kg (12.5 lbs)), while still providing sufficient resistance force to a user who can cause the input point to move at a comfortable speed along the defined path. It is evident that the ratio of the rotational speed of the output point to the rotational speed of the flywheel, as given by the aforementioned ratio, and the mechanical advantage obtainable, inter alia, by the distance L, help to determine the resistance force which is developed and presented to the drive member. There is a compromise between the momentum developed by the flywheel which helps to give a smooth movement to the handle, reducing the effect of “dead spots”, a feature (ie. smooth movement) which generally is more pronounced as the mass of the flywheel increases, and the size and mass of the exercise machine as a whole.[0032]

The resistance force may be varied by making use of a brake which acts on the flywheel and which is adjustable thereby to exert an adjustable braking force which restrains rotational movement of the flywheel.[0033]

The brake may be in the nature of a belt brake, a friction brake, an electromagnetic brake, a magnetic brake, or any equivalent component. The invention is not limited in this regard. The brake may be controlled automatically, eg. by means of suitable control electronics, to vary the braking force to suit the user, for example in a dynamic fashion. It then becomes possible to vary the path of movement of the input point and the resistance force in a controlled manner.[0034]

If drive is to be imparted by the handle to the resistance assembly, and not in the reverse direction, the exercise machine may include a unidirectional drive device between the handle and the resistance assembly. The drive device may be switchable or operable to change the direction (in a rotational sense) in which drive is imparted to the resistance assembly by the handle.[0035]

The unidirectional drive device may be in the nature of a ratchet device but any equivalent arrangement can be used. The invention is not limited in this regard.[0036]

A smooth, sweeping-type action can however be obtained if the handle is permanently connected to the flywheel, ie. if no uni-directional device is used, for the flywheel's momentum drives the handle through dead spots which could occur at extremities of the path of movement, and a continuous input of force is required of the user via the handle. It is imperative though for the resistance force, the mass of the flywheel, the radius of movement of the handle and the relationship between the rotational speed of the handle and the rotational speed of the flywheel to be carefully inter-related to ensure that the handle can be moved at a steady speed, which is not too fast to unbalance a user, against a resistance force of sufficient magnitude to provide a safe and effective workout.[0037]

In a preferred form of the invention, the exercise machine includes a base which, in use, provides a platform for a user, a support structure which extends upwardly from the base, a drive member which has an input point and an output point and which is connected to the support structure, a resistance assembly which is connected to the output point, and a handle connected to the input point whereby a user, on the platform, can grip the handle with two hands and rotate the handle about the output point against a resistance force which is generated by the resistance assembly.[0038]

The drive member may be of adjustable effective length to vary the distance between the input point and the output point, the drive member being rotatable about an axis which passes through the output point, and the resistance assembly may include a flywheel which is rotatable by rotational movement of the drive member. A drive arrangement may be connected between the output point and the flywheel to transfer drive to the flywheel at a suitable mechanical ratio.[0039]

The support structure may include upwardly extending supports which are pivotally movable relative to each other and the base may include a plurality of panels which are connected to lower ends of the supports. The resistance assembly may be attached to at least one of the supports and the base may be positioned on a side of the supports so that a user, on the base, is alongside the support structure and does not “straddle” the support structure, as is the case with the bicycle-type arm exercise machine previously referred to.[0040]

BRIEF DESCRIPTION OF THE DRAWINGS

The invention is further described by way of examples with reference to the accompanying drawings in which:[0041]

FIG. 1 is a side view of an exercise machine according to one form of the invention;[0042]

FIG. 2 shows the use, in different combinations, of two machines each of which is substantially the same as what is shown in FIG. 1;[0043]

FIGS. 3, 4,[0044]5 and6 are respectively a side view, an end view, a plan view and a view in perspective, of an exercise machine according to another form of the invention;

FIGS.[0045]7 to10 respectively correspond to FIGS.3 to6 and show the machine of FIGS.3 to6 in a collapsed or storage mode;

FIG. 11 shows another exercise machine according to the invention;[0046]

FIGS.[0047]12 to16 illustrate different methods of adjusting a rotational path which a user's hands follow when using the exercise machine of the invention;

FIGS.[0048]17 to23 show different handles which can be used with the machine of the invention;

FIGS. 24 and 25 illustrate two of the handles in use;[0049]

FIGS. 26 and 27 show a machine according to the invention fixed to a floor and a wall respectively;[0050]

FIGS.[0051]28 to30 illustrate different arrangements of the exercise machine of the invention; and

FIG. 31 shows the use in combination, from one end, of two machines each of the kind shown in FIGS.[0052]3 to6.

DESCRIPTION OF PREFERRED EMBODIMENTS

FIG. 1 of the accompanying drawings illustrates an[0053]

exercise machine

10 according to a first form of the invention.

The[0054]

machine

10 includes abase plate12 which is mounted to an upwardly extendingsupport column14 which has adrive shaft18 mounted, near opposed ends, to

bearings

20 and22 respectively. A relativelylarge drive pulley24 is fixed to the drive shaft slightly above thebearing20.

A[0055]

bevel gear

26 is fixed to an upper end of the drive shaft.

A cranked[0056]

member

28 which includes astub axle30, alever32 and a handle34, is fixed to an upper end of thesupport column14. The stub axle extends horizontally, is mounted to

bearings

36 and38, and is centred on an axis A which defines an output point to components which form a drive arrangement in the machine. Abevel gear40, which mates with thegear26, is fixed to the axle. At a position between thebevel gear40 and the bearing38 an optional one-way drive mechanism in the nature of a ratchet42 is installed. The arrangement is such that rotational drive can be transferred from thelever32 to thegear40, in one direction, but drive cannot be transferred from thegear40 to thelever32.

The mechanism, if used, can be switched to change the direction in which drive is transferred between the lever and the gear.[0057]

The handle[0058]34 may be movable along the length of thelever32 or thelever32 can be adjusted relatively to thestub axle30, so that the position of the handle34 can be adjusted relatively to the axle to a selected position shown in dotted lines34X.

A[0059]

thrust bearing

50 is mounted to the base plate. Anaxle52 extends upwardly from the thrust bearing and aflywheel54 is mounted to the axle. At its upper end theaxle52 is supported by means of abearing56.

A[0060]

pulley

58 is mounted to the axle above the upper surface of the flywheel and below thebearing56. Abelt62 couples thedrive pulley24 to thepulley58.

A[0061]

brake

66 is engaged with theflywheel54. The brake is adjustable to constrain rotational movement of theflywheel54 about theaxle56 to a greater or lesser extent. In this example the brake is a magnetic device of a kind which is known in the art. Any other type of brake could be employed, for example a belt which is engaged with the flywheel, a friction roller which bears on a rim of the flywheel, an electromagnetic brake, or the like. The invention is not limited in this regard.

A[0062]

cover

70 overlies the flywheel and thepulley24 and provides a platform upon which a user, not shown, can stand while using the exercise machine. In use of the machine the user's weight provides a ballast, or stabilising effect, which helps to keep the machine steady.

The[0063]

exercise machine

10 can be used in different ways. In one form of use the handle34, which forms an input point to the machine, is sufficiently lengthy so that a user, who stands on the cover, can grip the handle34 with both hands, one adjacent the other. The height of theaxle30 above theplatform70 and the length of the lever32 (between the handle and the stub-axle) are such that, as the user rotates the lever about theaxle30, the user must, at some stage, bend at the knees and, subsequently, move the arms from a lower position to an upper position. As thelever32 is rotated, rotational drive is transferred to thedrive shaft18 and drive is imparted by thedrive pulley20 and thebelt62 to the drivenpulley58. The flywheel is thereby caused to rotate against a braking effect exerted by themagnetic brake66. The brake can be adjusted to provide more or less resistance, according to requirement, to the rotational movement of the flywheel. The ratios of the various gears and pulleys in the drive arrangement from theaxle30 to theflywheel54 determine the mechanical advantage between the handle and the flywheel, a factor which helps to set the resistance force which is developed.

The exercise machine causes the user to exercise at least his legs, his arms and his upper torso while rotating the handle.[0064]

In a variation of the invention, the user, standing on the[0065]

platform

70, grips the handle34 with both hands while facing thecolumn14 as opposed to facing in a direction which is at a right angle to thestub axle30, as is the case in the former mode of use. The user rotates the handle34 using both hands, which move in unison, with a squatting and lifting type of body action.

In each mode of use the path of movement of the input point, formed by the handle[0066]34, is a closed loop of circular shape which lies in a vertical plane, and the user is either positioned adjacent the plane, facing in a direction which is generally parallel to the plane, or is positioned facing the plane, orientations which do not arise when use is made of a bicycle-type machine.

FIG. 2 illustrates an exercise machine[0067]80 which includes, in combination, afirst machine10 of the kind described in connection with FIG. 1 and asecond machine10A which is fundamentally the same as themachine10 and which is erected on asupport column16. Components of themachine10A which are the same as components of themachine10 are not described in detail and bear like reference numerals with the suffix “A”.

Although the[0068]

machine

10A could have a separate flywheel, in this example only one flywheel is used and the output drive of themachine10A is connected to theflywheel54 by means of a pulley60 which is mounted to theaxle52 below thebearing56, and abelt62A which couples thedrive pulley24A to the pulley60.

The handle[0069]34 can be coupled directly to thehandle34A using a connector82 which is shown in dotted outline. This means that the

members

28 and28A are movable in unison.

If the[0070]

handles

34 and34A are not directly connected the angular separation between the handles can be varied to any appropriate extent between 0° and 180°. FIG. 2 shows (in dotted lines for thehandle34A) the handles separated by about 180° with a gap84 between the handles which is occupied by a user. Again the path of movement of each input point (defined by each handle) is parallel to the direction in which the user faces.

FIGS.[0071]3 to6 illustrate anexercise machine90 according to another form of the invention from the side, from the end, in plan, and in perspective, respectively.

The machine includes[0072]

support structure

92 in the form of two elongate, inclined, upwardly extending

supports

94 and96 respectively which are pivotally connected to each other at upper ends98, directly or by means of intermediate structure such as a flywheel housing99, in a way which allows the supports, within reason, to be pivotally moved towards, and apart, from each other.

The machine includes a base[0073]100 which rests on the ground and which, in use, provides a platform, upon which a user, not shown, can stand while using the machine. In this example thebase100 includes three

panels

102,104 and106 respectively which are pivotally connected to one another at points108A and108B in a planar array. The base is fixed to lower ends of, and braces, the

110, within the housing99, is mounted to the support structure near the upper ends of thesupports98. The flywheel is driven by a small drive mechanism111 which is directly fixed to anaxle112 and ends of the axle are accommodated inbearings113 secured to the upper ends of the

supports

94 and96. The flywheel is relatively compact and weighs approximately 5 kg. It has been found through trial and experiment that a flywheel of this type is adequate for the purposes of the invention in that it is capable of providing sufficient resistance and a required degree of momentum, when used in the manner described hereinafter, but at the same is not unduly heavy or massive, a feature which enables the flywheel to be mounted to the upper ends of the supports.

A[0075]

brake

114 is used to provide a controlled restraining force which impedes free movement of the flywheel. Thebrake114 may be of any appropriate kind eg. a magnetic or an electromagnetic brake which is known in the art and, for this reason, the brake is not further described herein. By adjusting the brake in one direction a greater restraining force is exerted on the flywheel to impede free movement of the flywheel while, by adjusting the brake in an opposing direction, the restraining force which impedes movement of the flywheel is lessened.

The[0076]

axle

112 defines an output point oroutput axis116 for adrive member120 which is fixed to a protruding end of the axle.

The[0077]

drive member

120 includes ahollow section122, of rectangular dimensions, which is fixed to a protruding end of theaxle112 which extends towards thebase100, and anelongate member124 of rectangular cross section which is complementary to the internal shape of thehollow section122, and which is slidably located inside the hollow section.

The[0078]

member

124 is formed with a number ofholes126 at spaced locations along one side and afastener128, fixed to thehollow section122, can be engaged with a selected hole thereby to vary the effective length L of thedrive member120.

A[0079]

handle

130 is fixed to an outer end of themember124, which end is also referred as aninput point132 of thedrive member120, and the handle extends transversely to themember124 so that it overlies a part of thebase100.

The arrangement and orientation of the components of the exercise machine relatively to the base are such that a user can stand on the[0080]

base

100 and is able to grip thehandle130 with both hands with each hand curving around a grip portion of the handle ie. about an axis which is substantially at a right angle to the direction in which themember124 extends.

The user can rotate the handle about the axis on which the[0081]

axle

112 lies. In the process and during the rotation, depending on the effective length of thedrive member120, the user is compelled to a greater or lesser extent to bend at the knees and then to straighten the legs and reach upwardly with his arms in order to complete the rotational movement of thehandle130 about the axis on which theaxle112 lies.

The[0082]

handle

130 is aligned with what is referred to herein as aninput point132 to thedrive member120. The input point is the point at which a user inputs force or effort into the exercise machine and it is rotated through a closed circular path which lies in a substantially vertically plane. In the described mode of use the user stands adjacent the closed path and generally faces in a direction which is parallel to the plane of rotation. The drive arrangement has anoutput point116, aligned with theaxle112, at which the force generated by the user is transferred to the flywheel. The flywheel is rotatable against a resistance force generated by its inertia, frictional forces and the like. The primary resistance to movement, however, is generated by thebrake114 which, as noted, is adjustable.

During use of the machine, the mass of the user, who stands on the[0083]

base

100, acts to stabilise the exercise machine. This is an important factor for substantial forces can be generated on the machine during use thereof, particularly if the handle is rotated vigorously.

The machine can also be used in a way which has been described in connection with FIG. 1 in that a user can stand facing the flywheel and the plane in which the input point is rotated, looking basically in the longitudinal direction of the[0084]

axle

112, grip thehandle130 with both hands and rotate the handle using a swaying or swinging type motion with a corresponding leg-bending and leg-straightening action, the extent of which is determined by the height of the output point above the platform and the length of the lever between the input point and the output point.

FIG. 3 illustrates a defined[0085]

path

140, shown in dotted outline, along which theinput point132 moves during use of the machine. In this instance the path is circular for thedrive member120 is of a fixed length (L) during the use of the machine. This is not essential for, as is described hereinafter, the path may have a shape which can be varied automatically, or dynamically in response to the exercise action of the user.

To enable maximum benefit to be derived from the machine, the length of the[0086]

drive member

120 should be sufficiently great to ensure that the user must bend at the knees and then straighten the legs and raise the arms while rotating themember120. This type of action cannot be achieved with a “bicycle-type” exercise machine in which the user alternately exerts force on a resistance device with a left arm and a right arm. With this type of machine a support structure is normally positioned between two cranks which are respectively gripped by the user with the left hand and the right hand in a manner which causes the user's body to come close to the support structure. Clearly there is an inherent limitation to the maximum length of each crank. With the exercise machine of the invention, however, by displacing the drive arrangement to one side of the support structure, it is possible to increase the length of the drive to allow for at least two compound exercise movements each of which results in the user exercising the arms, the torso, the waist and the legs, in an aerobic manner, simultaneously.

The bicycle-type machine referred to does not include a support structure which is capable of handling a “one-sided” input of force by a user for the stability of this type of machine relies on the user being centrally positioned between the cranks so that one arm can push while the other arm pulls, and vice versa. With the machine of the invention however, the user's mass constitutes a ballast which, coupled to the cantilever-type arrangement of the base and the support structure, permits the user to stand adjacent the machine and exert force with both arms acting in unison and in the same direction.[0087]

FIG. 3 shows that the defined[0088]

path

140 has a maximum height X above a platform formed by thebase100 and a minimum height Y at a lowermost portion of the stroke of the handle, above the platform. The output point is a distance D above the platform and X=D+L and Y=D−L. A particularly advantageous form of the invention is realised if the ratio of X to Y is ≧2. Again it is pointed out, taking into account the height D of the output point above the platform, which typically is of the order of 1400 mm (55 inches), that this degree of relative movement is not achievable using a bicycle-type arm exercise machine of a kind which is known in the art.

FIGS.[0089]7 to10 correspond respectively to FIGS.3 to6 and illustrate theexercise machine90 as it is folded into a compact mode for storage or transport purposes. The supports94 and96 are pivoted towards each other and the

panels

102,104 and106 hinge relatively to each other, about the respective pivot points108, to provide a compact construction. Themember124 and thehandle130 can be detached, if required, from thehollow section122 to facilitate storage. This allows different handles, eg. of the kind described hereinafter, to be used with the machine.

The gear drive mechanism[0090]111 is shown schematically, in dotted outline, and is such that the rotational speed of the flywheel is at least20 times the rotational speed of the axle at the output point. Thus thehandle130 rotates at a speed which is substantially less than the rotational speed of the flywheel. On the other hand movement of the flywheel is constrained, as indicated, by thebrake114. The mechanical advantage which results from this type of arrangement enables the size of the flywheel to be reduced substantially typically, as indicated, to a mass of the order of5kg or even lower. The mechanism111 could include an appropriate gearbox, a belt drive or any other suitable arrangement.

FIG. 11 shows a machine[0091]90A which is similar to themachine90 and for this reason is not described in detail. Also like reference numerals are used to designate like components. A belt and pulley drive arrangement111A, of a kind similar to that described hereinafter, is used to rotate theflywheel110. The base100A include three slotted panels102A,104A and106A respectively which are fixed to laterally extending supports107 and109 respectively at lower ends of the inclined supports94A and96A. The panels can be moved to the planar orientation shown in FIG. 11, and to a folded arrangement similar to what is shown in FIG. 9, but the pivot points108A and108B cannot be moved downwardly below the FIG. 11 position, due to interlocking formations at abutting ends of the panels, a feature which helps to stabilise the machine in use.

FIG. 12 shows a drive member[0092]120A which includes anelongate member124A formed from two telescopically engaged parts124X and124Y respectively. The parts are joined by aspring160 which is positioned inside the part124X. In this example theaxle112 is mounted to apulley162 and drive is transferred to a resistance assembly, not shown, by means of abelt164 which is engaged with the pulley. The spring tends to pull the member124Y into the member124X and thereby decrease the radius of a path along which theinput point132 is moved. As the rotational speed of the handles increases, however, the radius of the defined path of movement increases in a dynamic fashion influenced, inter alia, by the vigour and force with which the user exercises.

FIG. 13 illustrates a drive member[0093]120B which is similar to that shown in FIG. 11 except that thespring160 is replaced by an elastic band160A.

FIG. 14 shows a drive member[0094]120C wherein a piston and cylinder assembly160B replaces thespring160. This assembly is double-acting in that forces are generated which tend to restrict movement of the piston into, and out of, the cylinder.

Another possibility is to use an elongate screw and nut arrangement, in the nature of a worm drive, to vary the length of the member. This can be done dynamically, or even automatically if use is made of a small electric motor to move the nut along the screw.[0095]

Clearly, with the arrangements shown in FIGS.[0096]12 to14, the force which is needed to rotate a flywheel can be varied dynamically, during use of the machine, without the need to stop and adjust the length of thedrive member120. In each case the input point moves along a path, which is dynamically variable, and forms a closed loop of variable shape which lies in a vertical plane.

FIG. 15 shows an arrangement, for setting the[0097]

drive member

120 at a fixed length, which is similar to what has been described in connection with FIGS.3 to4 in that amember124 is movable into, or out of, ahollow section122 which is mounted to anaxle112. At a chosen length the

members

122 and124 are fixed to one another by engaging a pin on afastener128 with acorresponding hole126 in themember124.

The[0098]

axle

112 is mounted to apulley162 which imparts rotational drive to the resistance assembly, not shown, by means of abelt164.

FIG. 16 shows a mechanical equivalent to the arrangement of FIG. 15 which provides for continuous, as opposed to stepwise, adjustment of the distance L, i.e., the distance between the[0099]

input point

132 and theoutput point116. Ascrew166 includes ashank168 which extends through aslot170 in ahollow section122. The shank is threadedly engaged with a complementary hole in themember124. The screw can be tightened when themember124 is at a selected position relatively to thehollow section122 in order to fix these components together.

FIGS.[0100]17 to19 illustrate different handle arrangements for use with the machine of the invention. In FIG. 17 ahandle130, in the form of an elongate shaft, is fixed to themember124. The handle has at least two

grip portions

176 and178, alongside one another, which enable a user to grip the handle with both hands, adjacent each other, with each hand curled around anaxis180 on which the shaft lies and which extends through theinput point132 which, upon being moved, forms the defined path or closedloop140. Theaxis180 is substantially at a right angle to a plane in which thepath140 lies.

FIG. 18 illustrates an arrangement wherein a[0101]

handle portion

130A is mounted via a flexible joint182, in the nature of a universal joint, to a handle portion130B which is immovably fixed to theelongate member124. Clearly thehandle portion130A is movable, to a greater or lesser extent, relative to the fixed handle portion130B during use of the exercise machine. Thehandle portion130A can provide sufficient space for two

grip portions

176 and178 for the two hands of a user. It is possible to remove the handle portion130B and connect the joint182 directly to themember124 as is indicated indotted lines124A.

FIG. 19 illustrates a handle[0102]130C which is also of compound construction. The handle130C includes a fixed handle portion130B which extends from theelongate member124. A second handle portion130D is connected to the handle portion130B. The handle portion130D includes atransverse component130F which is fixed, by means of abearing184, to ashort stub130G which, in turn, is fixed to the handle portion130B either immovably or by means of auniversal connector182 which allows pivotal movement of thecomponent130F, to a limited extent, relative to the portion130B. The bearing allows thecomponent130F to rotate about theaxis180 which passes through the input point138.

The handle arrangement shown in FIG. 19 is intended to be used by a person who stands on the[0103]

platform

100 looking generally in a direction which is substantially parallel to theaxis180. Thecomponent130F has two

grips

186 and188 respectively for the left and right hands of the user. The user can impart rotational drive to themember124 but with the user facing the plane in which the definedpath140 lies. Again it is required of the user to bend and straighten the legs to a greater or lesser extent depending on the effective radius or length of themember124. However the type of movement required of the user's body differs substantially from the movement required when a handle arrangement of the type shown in FIG. 17 is used. With the FIG. 19 arrangement, although the arms are again moved in unison, it is necessary for the user to sway the upper portion of the body to and fro and to reach upwards and downwards as the handle rotates.

FIG. 20 shows a[0104]

handle

130J in the form of a Z with

grips

176A and178A, which are parallel to each other and which are joined by a cross piece in the form of abar130K. Ashaft130L which is detachably and rotatably mounted to an input point (not shown) is coupled to a centre-point of thecross bar130K by a universal joint182A which allows thehandle130J to move with a pivotal action relatively to the shaft in a way which helps to reduce strain or stress on the user's arms and hands during use of the machine.

FIG. 21 shows that the[0105]

handle

130J can be coupled to theshaft130L by means of strong coil spring182B which is located on a centre line through the cross bar and which offers a degree of flexibility which is similar to that provided by the universal joint182A.

FIG. 22 shows the[0106]

handle

130J connected to the shaft by a flexible andstrong rubber bush182C which permits flexibility of the handle in all directions relatively to the shaft.

FIG. 23 shows a[0107]

handle

130M with aligned side-by-side grips176B and178B detachably fixed to a drive member120B by means of snap-fit fastener179. The grips are rotatable around a bearinghousing181.

As stated the machine can be designed so that it can be used with any of these handles (or other suitable handles) and, in each case the particular handle which is used creates different exercise characteristics.[0108]

FIG. 24 shows an exercise machine wherein a drive member[0109]120K is formed from articulated

components

122K and124K respectively connected to anoutput point116 byjoints182A and182B of the kind described in connection with FIG. 18. The effective length L of the drive member is dynamically adjustable, by the user, during use of the machine. The articulated connection allows the user to change his stance, on theplatform100, by moving his feet during use of the machine.

FIG. 25 shows a machine which uses articulated[0110]

joints

182C and182D between a handle130D of the type shown in FIG. 19 and atelescopic member120F of the type shown in FIGS. 12 and 13, to provide a drive, which is dynamically adjustable in length, to theoutput point116.

A preferred form of the invention is one wherein the[0111]

base

100, as shown in FIG. 3, forms a platform upon which a user stands whilst using the machine. The user's mass then provides sufficient stabilisation to ensure that the machine is stable during use. It is however not essential to use this type of construction and, in a more permanent arrangement, thesupport structure92 can include asmall pedestal190 which can be fixed to thefloor194, as is shown in FIG. 26. FIG. 27 shows that thesupport structure92 can includeformations196 eg. in the form of a spreader plate or connecting bar whereby the exercise machine can be attached, using suitable fasteners, to awall198.

Clearly with the arrangements shown in FIGS. 26 and 27 it is not possible for the machine to be dismantled with ease for storage or transport purposes.[0112]

It is also to be noted, referring to FIGS.[0113]24 to27, that a “step-up” drive system can be employed for increasing the rotational speed of theaxle112 which forms the output point of thedrive arrangement120. Referring for example to FIG. 27 theaxle112 is mounted to apulley162 which transfers drive via abelt164 to a relativelysmaller pulley162A. The smaller pulley drives a larger pulley162B which is connected to another smaller pulley162C by means of a second belt164A. Aflywheel110 which includes abrake114 is fixed to thesupport structure92 and is driven by an output shaft from the pulley164C.

FIG. 28 illustrates from the side an arrangement which is similar to what has been described in connection with FIG. 27 except that the[0114]

support structure

92 extends upwardly from a base100 which rests on the ground and is not fixed to the wall.

As used herein the word “axle” or “axis” is intended to include an actual axle and axis, as the case may be, and also a virtual axle or axis. The phrase “virtual axle or axis” is intended to cover a situation in which rotational movement takes place about a point which does not define a physical axle or axis, but merely a centre of rotation. This type of arrangement is shown in FIGS. 29 and 30 respectively which illustrate an exercise machine similar to what has been described in connection with FIG. 28, wherein the[0115]

support structure

92 supports acircular support frame200. Awheel202 is mounted inside the circular support frame and runs onrollers204 which are fixed at spaced locations to the wheel. The rollers in turn ride inside a hollow guide or track, on an inner surface of the support frame, indicated indotted outline206.

A[0116]

pulley

162 is fixed to a central point on thewheel202. The pulley drives abelt164 which, in turn, drives asmaller pulley162A which is mounted to a larger pulley164B. The pulley164B drives a belt164A which is connected to a smaller pulley164C which drives aflywheel110 to which is fitted abrake114. It can be seen that the arrangement in FIGS. 29 and 30 is similar to what has been described in connection with FIG. 27 except that thewheel202, riding inside thesupport frame200, simulates a fixed axle by providing avirtual axle216 which defines the output point of thedrive member120.

In this example the drive member includes a[0117]

plate

220 which normally is fixed to, and covers, thewheel202 and which is formed with a number ofholes222 at spaced intervals extending from thevirtual axis216. Ahandle224 can be engaged with a selected hole which defines theinput point132. The user can, as before, grip the handle with both hands and cause it to rotate along a defined circular path centred on thevirtual axis216 which coincides with theoutput point116. A step-up drive is achieved to the flywheel which is braked, to a required extent, by thebrake114. In all other respects the operation of the exercise machine is substantially the same as what has been described.

FIG. 31 shows a compound machine which, in many respects, is similar to that shown in FIG. 2, and which is basically a combination of two[0118]

machines

90F and90G each of which is similar to themachine90 in FIG. 3. Each machine has its own flywheel. The

handles

130F and130G of the machines can be joined by acoupling bar230 or they can be displaced to form a gap232 between the handles which can accommodate a user. If the handles are not joined they can be angularly displaced by up to1800, as shown by dotted lines for thehandle130G. These features allow for a multitude of different types of usage.

Claims

What is claimed is:

1. An exercise machine comprising:

a support structure;

a resistance assembly connected to the support structure;

a drive member having an output point from which force is applied to the resistance assembly and an input point which is spaced from the output point by a distance L; and

at least one handle acting on the drive member at the input point and which a user can engage and move, in a continuous, load-exerting manner, against a resistance force generated by the resistance assembly.

2. The exercise machine according toclaim 1, wherein said at least one handle comprises one handle with which one hand of the user is engageable.

3. The exercise machine according toclaim 1, wherein the at lease one handle is such that two hands of the user are engageable therewith.

4. The exercise machine according toclaim 1, wherein the user's arms act in unison on the handle against the resistance force.

5. The exercise machine according toclaim 1, wherein the input point is movable along a path which forms a closed loop.

6. The exercise machine according toclaim 5, wherein the path is a defined circular path.

7. The exercise machine according toclaim 5, wherein the closed loop lies in a substantially vertical plane.

8. The exercise machine according toclaim 5, wherein the shape of the closed loop is dynamically variable.

9. The exercise machine according toclaim 1, further comprising at least one member which is adjustable to vary the distance L.

10. The exercise machine according toclaim 9, wherein the at least one member is adjustable against a biasing element.

11. The exercise machine according toclaim 9, further comprising a releasable fastener acting on the at least one member for preventing the distance L from varying after adjustment.

12. The exercise machine according toclaim 9, wherein the at least one member is rotatable by the handle about the output point.

13. The exercise machine according toclaim 5, wherein the at least one handle includes grips for the user's hands, the grips being positioned so that the user's hands, when engaged with the grips, extend around a common axis which is transverse to the closed loop.

14. The exercise machine according toclaim 5, further comprising an input axis which is transverse to the closed loop and which extends through the input point, wherein the at least one handle includes grips for the user's hands which are positioned on respective opposed sides of of said input axis.

15. The exercise machine according toclaim 14, wherein the grips are rotatable in unison about the input axis.

16. The exercise machine according toclaim 1, wherein the support structure extends upwardly and includes a base which is attachable to a floor to stabilise the support structure during use.

17. The exercise machine according toclaim 1, wherein the support structure extends upwardly and includes formations for attaching the support structure to a wall to stabilise the support structure machine during use.

18. The exercise machine according toclaim 1, wherein the support structure extends upwardly, the exercise machine further comprising a base attached to a lower end of the support structure and providing a platform upon which the user stands so that the user's mass stabilises the support structure during use thereof.

19. The exercise machine according toclaim 6, wherein the circular path has a highest point which is a distance X above a ground reference level on which the user stands and a lowest point which is a distance Y above the ground reference level and wherein X≧2Y.

20. The exercise machine according toclaim 1, wherein the support structure has two upwardly extending supports, the resistance assembly being mounted to at least one of the supports, and includes a base which interconnects lower ends of the supports and forms a platform upon which the user stands.

21. The exercise machine according toclaim 20, wherein the supports are pivotally movable towards, and away from, each other.

22. The exercise machine according toclaim 20, wherein the base includes a plurality of pivotally interconnected panels.

23. The exercise machine according toclaim 20, wherein the resistance assembly includes a flywheel which is rotatable about an axis disposed near upper ends of the supports.

24. The exercise machine according toclaim 20, wherein the drive member is adjustable to vary the distance L.

25. The exercise machine according toclaim 24, wherein the handle includes an elongate shaft extending transversely from the drive member, said elongate shaft being of sufficient length to provide grips for the user's hands.

26. The exercise machine according toclaim 1, further comprising a drive arrangement which is connected to the drive member at the output point, and which is connected directly or indirectly to the resistance assembly, said drive arrangement increasing the force generated by the resistance assembly and presented to the drive member.

27. The exercise machine according toclaim 26, wherein the resistance assembly includes a flywheel and the input point is movable along a circular path, the drive arrangement being such that the ratio of the rotational speed of the flywheel to the rotational speed of the drive member around the input point is greater than20.

28. The exercise machine according toclaim 1, further comprising a unidirectional drive device for transferring force from the input point to the resistance assembly.

29. The exercise machine according toclaim 1, wherein the resistance assembly includes a flywheel and a brake which acts on the flywheel and is adjustable to exert an adjustable braking force restraining rotational movement of the flywheel.

30. In combination, first and second exercise machines, each exercise machine being according toclaim 1, the exercise machines being positioned so that the support structure of the first exercise machine is spaced from and opposes the support structure of the second exercise machine, with the handle of the first exercise machine being at a selected angular position relatively to the handle of the second exercise machine.

31. The combination ofclaim 30, wherein the resistance assembly of the first exercise machine comprises the resistance assembly of the second exercise machine.

32. The combination ofclaim 30, wherein the handles are at the same angular orientation and are connected directly to each other.

33. The combination ofclaim 30, wherein the handles are spaced from each other and form a gap between them which accommodates a user who can grip one handle with one hand and the other handle with the other hand.

34. An exercise machine comprising:

a base for providing a platform for a user during use;

a support structure extending upwardly from the base;

a drive member having an input point and an output point and being connected to the support structure;

a resistance assembly connected to the output point; and a handle connected to the input point, wherein a user on the platform can grip the handle with two hands and rotate the handle about the output point against a resistance force which is generated by the resistance assembly.

35. The exercise machine according toclaim 34, wherein the drive member has a length that is adjustable to vary a distance between the input point and the output point, the drive member being rotatable about an axis which passes through the output point, the resistance assembly having a flywheel which is rotatable by rotational movement of the drive member.

36. The exercise machine according toclaim 35, further comprising a brake for acting on the flywheel and is adjustable to exert an adjustable braking force for restraining rotational movement of the flywheel.

37. The exercise machine according toclaim 35, further comprising a unidirectional drive device for transferring force from the input point to the resistance assembly.

38. The exercise machine according toclaim 35, wherein the support structure includes upwardly extending supports pivotally movable relatively to each other, and the base includes a plurality of panels which are connected to lower ends of the supports.

39. The exercise machine according toclaim 38, wherein the resistance assembly is mounted to at least one of the supports.

40. The exercise machine according toclaim 35, further comprising a drive arrangement between the output point and the flywheel to increase the rotational speed of the flywheel relatively to the rotational speed of the drive member.

41. An exercise machine comprising:

a support structure;

a resistance assembly connected to the support structure;

a drive member having an output point from which force is applied to the resistance assembly and an input point spaced from the output point; and

at least one user engaged handle for acting on the drive member at the input point against a resistance force generated by the resistance assembly, the input point being movable along a path which forms a closed loop having a highest point which is a distance X above a ground reference level on which the user stands and a lowest point which is a distance Y above the ground reference level and wherein X≧2Y.

42. An exercise machine comprising:

a support structure;

a resistance assembly connected to the support structure for generating a resistance force;

a user engaged movable handle acting on the drive member at the input point, wherein the user's arms act in unison against the resistance force which is generated by the resistance assembly.

43. An exercise machine comprising:

a support structure;

a drive member having an output point from which force is applied to the resistance assembly and an input point spaced from the output point;

at least one user engaged movable handle acting on the drive member at the input point and against the resistance force; and

a base attached to a lower end of the support structure and which provides a platform upon which the user stands so that the user's mass stabilises the support structure during movement of the handle.

44. An exercise machine comprising:

a support structure;

at least one handle which acting on the drive member at the input point and which a user can engage and move against the resistance force generated by the resistance assembly, the input point being movable along a path which lies in a substantially vertical plane, the handle being positioned so that it can be engaged by a user in at least one of the following positions: a position in which the user is adjacent the path and generally faces the vertical plane, and a position in which the user is adjacent the path and generally faces in a direction which is substantially parallel to the plane.

45. A handle arrangement for inputting force to an exercise machine comprising;

a cross piece;

a pivotally movable joint located on a centre line through the cross piece; and

first and second hand grips on or connected to the cross bar on opposed sides of the centre line.

46. The handle according toclaim 45, further comprising a connector positioned on the centre line for allowing at least the cross piece to be rotated about the centre line.