Treadmill with adjustable cushioning members

BACKGROUND OF THE INVENTION

1. The Field of the Invention

The present invention relates to treadmills. More specifically, the present invention relates to treadmills with adjustable cushioning members that selectively cushion the impact caused by users when operating the treadmills.

2. Background and Related Art

Treadmills have become increasingly popular in recent years as exercise equipment that is used for either running or walking. Treadmills typically include an exercise platform having an elongate frame with a roller assembly mounted across opposite lateral ends of the frame. A belt is mounted for travel about the roller assembly and is controlled by a motor. The belt is flexible and unable to rigidly support the weight of the user. As such, a user is typically supported by a deck that is disposed between the upper portion of the belt and the frame and is made of a rigid material. As the user walks or runs on the belt, the belt is pressed against the underlying deck to provide mechanical support.

Some treadmills include decks that are directly affixed to the frame to provide a rigid support. As a result, the shock delivered to the deck from the user's step is reflected back to the foot, ankle and/or leg of the user in a similar manner as the reactive forces are imposed on a walker, a jogger or a runner exercising on a hard-paved surface or a sidewalk. Over long periods of time, the shock experienced by the user may provide detrimental effects to the joints of the user. Even in the short term, exercising on a rigid surface may prove to be tiring and jarring to a user. Attempts have been made to provide a way to cushion the impact reflected back to a user while still providing a rigid surface to support the belt and the user.

One method of attempting to cushion the impact reflected to a user is to provide an intricate shock absorbing system, which is attached to both the frame and the deck. However, the intricate shock absorbing system has proven to be difficult to manufacture and cost prohibitive. Another method includes attaching rubber blocks or cushioning strips along the length of the frame prior to mounting the deck to the frame. However, the rubber blocks or cushioning strips have proven to perform differently from one user to another due to the individual weight of the users. As a result, at times the cushioning has proven to be insufficient while at other times the cushioning has proven to be excessive, depending on the user. Another method includes the use of elastomeric springs that are positioned between the frame and the deck to provide an amount of resistance that is proportional to the extent that the deck deflected by a user while exercising.

Each user exercising on a treadmill does not cause the same amount of deflection. Furthermore, the amount of cushioning needed also depends upon the exercise that the user performs on the treadmill. For instance, running on the treadmill tends to require more cushioning than walking on the same treadmill. In addition, the amount of cushioning desired varies from user to user according to personal taste. As such, it would therefore be an advancement in the art to provide a treadmill that offers differing amounts of cushioning. A traditional attempt to provide individualized cushioning required physically removing strips of cushioning material and inserting other strips into the treadmill to selectively provide a desired amount of cushioning. This method proved to be time consuming and awkward.

As such, what is needed is a treadmill in which a user may selectively adjust the amount of cushioning provided without having to disassemble and remove pieces of the treadmill.

SUMMARY OF THE INVENTION

It is, therefore, an object of the present invention to provide a treadmill with a cushioning mechanism that can be selectively adjusted to provide differing amounts of cushioning to a user exercising on the treadmill.

It is another object of the present invention to provide a treadmill that can be conveniently adjusted to provide differing amounts of cushioning without disassembling the cushioning mechanism.

It is yet another object of the present invention to provide a treadmill with a cushioning mechanism that can be conveniently adjusted to provide differing amounts of cushioning depending on the different type of exercises to be performed on the treadmill.

A further object of the present invention is to provide a treadmill with a cushioning mechanism that can be selectively adjusted to provide differing amounts of cushioning based on individual preferences.

To achieve the foregoing objects, and in accordance with the invention as embodied and broadly described herein a treadmill with an adjustable impact absorbing mechanism is provided. The impact absorbing mechanism is configured to adjustably cushion the impact of a user exercising on the treadmill. The adjustable impact absorbing mechanism allows the user to select an amount of cushioning provided by selectively adjusting the impact absorbing mechanism.

The treadmill comprises a frame and an endless belt trained on the frame, wherein the belt has an upwardly exposed exercise section. A deck is disposed between the exercise section of the belt and the frame. A plurality of cushioning members are positioned on opposing sides of the frame such that each of the cushioning members includes a plurality of portions with different cushioning properties. The cushioning members are configured to be adjustable so as to selectively position a portion of the cushioning members between the frame and the deck and are mechanically interconnected such that movement of one of the cushioning members results in corresponding movement of the other cushioning members.

One embodiment includes an adjustable, flexible cantilever that comprises a flexible arm and a bumper. The arm includes one end that is mounted to the frame and the other end that is freely disposed from the frame. The bumper extends between the free end and the deck. The cantilever also includes a brace mounted to the frame adjacent to the cantilever, wherein the brace may be selectively moved along the length of the cantilever.

Another embodiment comprises an impact absorbing mechanism having a plurality of cushioning members that each rotate in a horizontal plane. Each cushioning member has a plurality of portions, each portion having different cushioning properties. Horizontal rotation of each cushioning member adjusts the amount of cushioning between the deck and frame. The cushioning members may have indicia thereon, e.g., numbers, that can be viewed by a user to determine the amount of cushioning selected.

In another embodiment, the impact absorbing mechanism comprises: (i) a spring; and (ii) a screw configured to extend therethrough. The screw is positioned in a hole that extends through the frame and/or treadmill deck. The pitch of the screw threads and the spring coil frequency correspond such that the screw threads within the inner diameter of the spring. As such, the rotation of the screw selectively extends or contracts the effective length of the spring, depending on the direction of rotation. Thus, adjustment of the screw correspondingly adjusts the degree of cushioning.

Additional objects, features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by the practice of the invention. The features and advantages of the invention may be realized and obtained by means of the instruments and combinations particularly pointed out in the appended claims. These and other features of the present invention will become more fully apparent from the following description and appended claims, or may be learned by the practice of the invention as set forth hereinafter.

BRIEF DESCRIPTION OF THE DRAWINGS

In order to describe the manner in which the above-recited and other advantages and features of the invention can be obtained, a more particular description of the invention briefly described above will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings. Understanding that these drawings depict only typical embodiments of the invention and are not therefore to be considered to be limiting of its scope, the invention will be described and explained with additional specificity and detail through the use of the accompanying drawings in which:

FIG. 1

is partial cutaway perspective view of a treadmill having an exemplary embodiment of a cushioning mechanism;

FIG. 2

is a partial cross-sectional elevation view of the cushioning mechanism shown in

FIG. 1

taken along section line

2

—

2

therein;

FIG. 3

is a partial cross-sectional elevation view of another exemplary embodiment of a cushioning mechanism;

FIG. 4

is a partial cross-sectional elevation view of another exemplary embodiment of a cushioning mechanism;

FIG. 5

is a partial cross-sectional elevation view of another exemplary embodiment of a cushioning mechanism;

FIGS. 6A-6C

feature partial cross-sectional elevation views of another exemplary embodiment of a cushioning mechanism;

FIG. 7

is a partial cutaway perspective view of a treadmill having another exemplary embodiment of a cushioning mechanism;

FIG. 8

is a partial cross-sectional elevation view of the cushioning mechanism of

FIG. 7

taken along section line

8

—

8

therein;

FIG. 9

is a partial cutaway top elevation view of another exemplary embodiment of a cushioning mechanism;

FIG. 10

is a partial cross-sectional elevation view of another exemplary embodiment of a cushioning mechanism;

FIG. 11

is a partial cross-sectional perspective view of another exemplary embodiment of a cushioning mechanism;

FIG. 12

is a partial cut-away top elevation view of another exemplary embodiment of a cushioning mechanism;

FIG. 13

is a perspective view of a treadmill having another exemplary embodiment of a cushioning mechanism;

FIG. 14

is a bottom view of a cushioning member of the treadmill featured in

FIG. 13

shown adjacent a deck illustrated in a cutaway, exploded view;

FIG. 15

is a cutaway top view of the treadmill of

FIG. 13

with first and second cushioning members of the cushioning mechanism shown partially in phantom views;

FIG. 16

a

is a top view of a cushioning member frame with cushioning pads shown in a cutaway view mounted therein.

FIG. 16

b

is a bottom view of the cushioning member frame of

FIG. 17

a

without the pads shown therein;

FIG. 17

is a cutaway top view of an alternate treadmill having the cushioning mechanism of

FIG. 14

therein (shown partially in phantom lines) and having an aperture through the deck and side rail to thereby view a selected cushioning setting;

FIG. 18

is a bottom view of an alternate cushioning member with numbers indicating different cushioning portions shown in phantom lines;

FIG. 19

is a partially cutaway side view of an alternate treadmill having an aperture through the treadmill side rail and deck to thereby allow viewing of the number shown in phantom view in FIG.

18

.

FIG. 20

illustrates another exemplary embodiment of a cushioning mechanism comprising a spring and a screw selectively mounted therein. The screw is shown in a cross sectional view.

DETAILED DESCRIPTION OF THE INVENTION

The present invention relates to treadmills with an impact absorbing mechanism that is configured to selectively adjust the cushioning of a user's impact. Depicted in

FIG. 1

is one embodiment of a treadmill incorporating the features of the present invention. The adjustable impact absorbing mechanism in the present invention allows a user to select the amount of cushioning that will be provided by selectively adjusting the impact absorbing mechanism to individualize the amount of cushioning for a specific user as well as for a particular type of exercise. The adjustments made by a user to the impact absorbing mechanism are done without any disassembly of the treadmill.

As illustrated in

FIG. 1

, one embodiment of a treadmill

10

includes an exercise base and a support structure

14

. Support structure

14

comprises a handrail

16

that extends upwardly from exercise base

12

and a feet means for supporting treadmill

10

upon a support surface such as a floor. One example of feet means is illustrated as feet

18

, which are located on both the right side of handrail

16

and on the left side of handrail

16

, wherein left and right are defined when a user is facing support structure

14

while standing on exercise base

12

.

Handrail

16

may comprise an optional control console

17

that is attached to the upper end of handrail

16

and extends laterally over exercise base

12

. Console

17

may have an operating control such as an actuator switch to operate treadmill

10

and an indicator means that may be operated by the user to determine various parameters associated with the exercise being performed. Console

17

may also include a cup or glass holder so that the user may position a liquid refreshment for use during the course of performing the exercise. Those skilled in the art will appreciate that various embodiments of consoles may be used. In fact, console

17

may only include on/off switch and therefore may be completely replaced by a lateral support member.

Exercise base

12

includes a front end

20

and a back end

22

. As illustrated in

FIG. 1

, front end

20

of exercise base

12

is attached to support structure

14

and is rotatably attached to support structure

14

such that exercise base

12

may be rotated between an operational position, (illustrated in

FIG. 1

) and a storage position in which exercise base

12

is substantially vertical. Those skilled in the art will appreciate that various other methods of attaching exercise base

12

to support structure

14

are equally effective in carrying out the intended function thereof. In addition, there is no requirement that exercise base

12

be rotatable. It is contemplated that exercise base

12

can be fixedly attached to support structure

14

.

Referring to

FIG. 1

, exercise base

12

comprises a frame

24

that includes a right frame member

28

and a left frame member (not shown). In

FIG. 1

, however, only the right side of treadmill

10

is visible. It is intended that the left side of frame

24

be a mirror image of the structure discussed relative to the right side. Right frame member

28

and left frame member (not shown) are in a spaced-apart, longitudinal relationship and are substantially parallel. Exercise base

12

also comprises a rear support member

30

that is attached to right frame member

28

and left frame member (not shown) at back end

22

of exercise base

12

.

Exercise base

12

comprises a front roller

34

and a back roller

36

that are attached laterally near front end

20

and back end

22

of frame

24

, respectively. An endless belt

32

is trained over front roller

34

and back roller

36

and is positioned between right frame member

28

and left frame member (not shown) so that belt

32

includes an upwardly exposed exercise section

38

upon which a user exercises.

As depicted in

FIGS. 1 and 2

, exercise base

12

includes a deck

40

that is disposed between exercise section

38

of belt

32

and frame

24

. Deck

40

is substantially rigid and provides a rigid support to a user exercising on exercise section

38

of belt

32

. Deck

40

and belt

32

are configured to receive a user thereon for the performance of exercise, including walking, running, jogging and other similar related activities. Treadmill

10

may also be used for stationary exercises such as stretching or bending while the user is standing on belt

32

.

In one embodiment, the front end

20

and/or back end

22

of deck

40

are not secured to the frame. Instead, end

20

and/or

22

move freely from frame

24

to permit a greater adjustment of cushioning. For example, in one embodiment, the back end

22

of deck

40

is secured to frame

24

(through the use of screws, or similar connectors), but the front end

20

of deck

40

is not secured to frame

24

. As such, the front end

20

deflects freely from frame

24

to permit a greater adjustment of cushioning applied to the front end

20

of deck

40

.

However, in another embodiment, both front end

20

and back end

22

of deck

40

are secured to frame

24

and an adjustable cushioning is applied to the central portion of deck

40

between opposing ends

20

and

22

. Optionally, the adjustable cushioning may be applied in front and/or in back of the points of securement of deck

40

to frame

24

.

One embodiment of right frame member

28

and left frame member (not shown) comprises a side rail

42

and a side platform

44

. As illustrated in

FIG. 1

, side platform

44

is positioned over the top of side rail

42

of both right frame member

28

and left frame member (not shown). Side platforms

44

are positioned on each side of belt

32

and are capable of supporting the weight of a user standing thereon.

The position of side platforms

44

are such that a user of treadmill

10

can comfortably and easily step off of belt

32

onto one or both of side platforms

44

. A user can also stand on side platform

44

on either side of exercise base

12

until he or she is ready to step onto belt

32

. It can be appreciated that other embodiments of frame

24

that include right frame member

28

and left frame member (not shown) or the components thereof are equally effective in carrying out the intended function thereof.

The present invention includes an impact absorbing mechanism

48

that is configured for manual adjustment to provide selectable amounts of impact cushioning when a user is operating on exercise section

38

of belt

32

. Impact absorbing mechanism, which is an example of an impact absorbing means, allows the amount of cushioning provided by treadmill

10

to be manually adjusted to individualize treadmill

10

for different uses and/or users.

One embodiment of impact absorbing mechanism

48

is depicted in

FIGS. 1 and 2

. In

FIG. 1

, impact absorbing mechanism

48

comprises a plurality of cushioning members

50

that are positioned between deck

40

and frame

24

. Although

FIG. 1

illustrates two (2) cushioning members

50

, it can be appreciated that various other numbers of cushioning members

50

may be used. Cushioning members

50

are attached to opposing sides of frame

24

and are at least partially disposed between frame

24

and deck

40

. Cushioning members

50

are substantially opposite to each other on frame

24

and are substantially perpendicular to deck

40

. Cushioning members

50

comprise a plurality of portions having different cushioning properties. In

FIG. 1

, cushioning members

50

are attached to the inside surface of frame

24

. It is contemplated, however, that cushioning members

50

may be attached to the outside surface of frame

24

and perform the function thereof equally effectively.

Cushioning members

50

comprise flexible bases

58

that include apertures

52

of varying sizes. As the size of aperture

52

increases, the stiffness of that portion of base

58

cushioning members

50

decreases. As a result, the size of aperture

52

in base

58

of cushioning members

50

is related to the flexibility provided by that portion of cushioning members

50

. The portions of cushioning member

50

include different cushioning properties due to the varying size of the apertures to allow a user of treadmill

10

who may desire less cushioning, for example, to manually adjustably position cushioning members

50

so that the portion of cushioning members

50

with the smallest aperture

52

and, therefore, the least flexibility is proximate to deck

40

. In this position, cushioning members

50

have an increased stiffness that results in less cushioning. In contrast, when more cushioning is desired, cushioning members

50

are rotated to adjust cushioning members

50

so that a portion of bases

58

with progressively increasing sized apertures is against deck

40

to increase the flexibility and cushioning of cushioning members

50

.

As shown in

FIGS. 1 and 2

, bases

48

of cushioning members

50

are configured in a disk-like shape. While bases

58

, as shown, are substantially planar, it is not required that bases

58

be planar. Instead, bases

58

may have various other configurations such as elliptical, oval, or octagonal. The shape of bases

58

is not particularly important since various other configurations of bases

58

are equally effective in carrying out the intended function thereof. What is important is that bases

58

of cushioning members

50

have portions of differing amounts of stiffness to correspondingly provide different amounts of cushioning in absorbing the impact between deck

40

and frame

24

when a user is operating on exercise section

38

of belt

32

. Cushioning members

50

provide selectable amounts of impact cushioning.

As illustrated in

FIG. 1

, impact absorbing mechanism

48

also comprises means for selectively adjusting cushioning members

50

so as to selectively position one of the plurality of portions of cushioning members

50

between frame

24

and deck

38

. For example, manually a user may be able to physically move or rotate cushioning members

50

or press a button on console

17

to cause cushioning members

50

to be automatically and selectively adjusted to provide the desired amount of cushioning.

One example of a structure capable of performing the function of such a means for selectively adjusting cushioning members

50

comprises a handle

56

. As depicted in

FIG. 1

, one embodiment of handle

56

is mounted outside frame

24

and is attached to one of cushioning members

50

. Handle

56

is configured to cooperate with frame

24

. Other embodiments of handle

56

perform the function thereof equally effectively. For example, handle

56

may be a knob attached to base

58

of one of cushioning members

50

, particularly if cushioning members

50

are attached to the outside surface of frame

24

. Handle

56

may be elongated, oval, round, square, or may include various other geometric shapes. Handle

56

must just be something that the user can easily grasp. Other embodiments of handle

56

may include some type of an elongated lever or rod. If means for selectively adjusting cushioning members

50

is mounted on console

17

, it may comprise a button that is indexed to automatically and incrementally adjust cushioning members

50

to the specific amounts of cushioning. Other embodiments of means for selectively adjusting cushioning members

50

are some sort of a lever that is slidable on console

17

or a knob attached to console

17

that may be selectively rotated. Either the knob, the lever or some other embodiment may be moved on the console

17

by the user to position bases

58

of cushioning members

50

to corresponding positions to provide the selected amount of cushioning.

Impact absorbing mechanism

48

may optionally comprise means for mechanically interconnecting cushioning members

50

such that movement of one of cushioning members

50

results in corresponding movement of the other second cushioning members

50

. One embodiment of structure capable of performing the function of such a means for mechanically interconnecting the plurality of cushioning members

50

comprises an elongated axle

54

that is depicted in FIG.

1

. Axle

54

is attached to cushioning members

50

and extends laterally therebetween. As the user of treadmill

10

adjusts one of cushioning members

50

using handle

56

to select the desired amount of cushioning, axle

54

translates the movement to the remaining cushioning members

50

. Consequently, all of cushioning members

50

move substantially simultaneously to the selected position to provide the desired amount of cushioning.

As illustrated, axle

54

is substantially round. Axle

54

could, however, have other embodiments such as a square, an oval, a rectangle, or another shape. Various other configurations of means for mechanically interconnecting first and second cushioning members

50

are capable of performing the function thereof equally effectively. Alternatively, means for mechanically interconnecting cushioning members

50

may comprise a linkage or a cable as will be discussed in further detail below.

In those embodiments of impact absorbing mechanism

48

that do not comprise a means for mechanically interconnecting cushioning members

50

, all of cushioning members

50

have means of adjusting cushioning member

50

so as to selectively position or select one of the plurality of portions

58

of cushioning member

50

between frame

24

and deck

40

. For example, as depicted in

FIG. 1

, first and second cushioning members

50

may each have a handle, such as handle

56

, attached thereto. This embodiment would require a user to first make the adjustment to first cushioning member

50

located on one side of treadmill

10

and then move to the opposite side to manually adjust to second cushioning member

50

or vice versa. The drawback with this embodiment is in that a user might forget to adjust cushioning members

50

on the opposite side or may inadvertently adjust only cushioning members

50

on one side of treadmill

10

resulting in cushioning members

50

having different settings.

A variety of different adjustable cushioning members may be provided along the length of the base

12

in order to provide a substantially horizontal deck

40

. It is also possible to employ both adjustable and non-adjustable cushioning members between frame

24

and deck

40

in order to provide a substantially horizontal deck

40

.

The remaining figures illustrate other embodiments of impact absorbing mechanisms and cushioning members. The majority of features previously discussed relative to

FIGS. 1 and 2

apply to the remainder of the figures.

FIG. 3

depicts another embodiment of impact absorbing mechanism

66

. One of a plurality of cushioning members

68

is shown in FIG.

3

. Impact absorbing mechanism

66

comprises a plurality of substantially identical cushioning members

68

that is movably attached to frame

24

and is substantially perpendicular to deck

40

. As with cushioning members

50

, cushioning members

68

each may be attached either inside or outside frame

24

.

Cushioning members

68

comprise a plurality of portions having different cushioning properties. Cushioning members

68

each comprise a base

72

having a plurality of arms

70

projecting therefrom. In the embodiment depicted in

FIG. 3

, base

72

is substantially round. Various other configurations of base

72

are capable of performing the function thereof with equal effectiveness. Base

72

could, for example, alternatively be square, oval, elliptical, octagonal, triangular, or another shape. Arms

70

project radially from base

72

. While

FIG. 3

illustrates that cushioning members

68

have four (4) arms

70

, it is contemplated that any number of arms

70

other than one (1) can be utilized. What is important is that the user can manually adjust cushioning members

68

to select between differing amounts of cushioning. Arms

70

and base

72

are substantially parallel.

Arms

70

of cushioning members

68

are made of various materials with each having a different stiffness characteristic such that each of arms

70

experiences a differing amount of deflection when contacting deck

40

in response to a force from the impact of a user on exercise section

38

of belt

32

. In one embodiment of cushioning members

68

, arms

70

are substantially comprised of materials selected from the group consisting of plastic, hard rubber, soft rubber, and cellular foam. Various other kinds of materials that have differing stiffness characteristics may alternatively be used. In addition, although depicted in

FIG. 3

as being substantially rectangular, arms

70

may have other configurations such as being square, semispherical, half an ellipse, half an oval, or a truncated cone and perform the function thereof equally effectively.

FIG. 4

illustrates another embodiment of an impact absorbing mechanism

80

that comprises cushioning members

82

. Like cushioning members

50

and

68

depicted in

FIGS. 1-3

, cushioning members

82

are movably attached to frame

24

and are disposed substantially perpendicular to deck

40

. Cushioning members

82

comprise a plurality of portions having different cushioning properties. Cushioning members

82

comprise a base

92

with arms

84

extending therefrom. In this embodiment, cushioning members

82

are substantially fan-shaped. Like cushioning members

68

depicted in

FIG. 3

, cushioning members

82

have arms

84

extending outwardly from base

92

. In this embodiment, as illustrated in

FIG. 4

, cushioning members

82

have three (3) arms

84

. As previously mentioned, cushioning members

82

could, however, have various other numbers of arms

84

.

Although cushioning members

68

and

92

illustrated in

FIGS. 3 and 4

have arms

70

and

84

, respectively, that are parallel to bases

72

and

92

, respectively, arms

70

and

84

are not required to be parallel to bases

72

and

82

. Instead, bases

72

or

92

could be mounted on frame

24

so as to be substantially parallel with deck

40

. Arms

70

or

84

while extending outwardly from bases

72

or

92

now extend upward toward deck

40

. For example, arms

70

and

84

could be “L-shaped.” This embodiment of cushioning members performs the function thereof equally effectively.

Impact absorbing mechanism

80

includes an optional raised portion

86

on deck

40

that extends away from deck

40

toward frame

24

. Raised portion

86

is configured to cooperate with arms

84

on cushioning members

82

. Alternatively, raised portion

86

of deck

40

can be eliminated and arms

84

of cushioning members

82

extended to directly contact deck

40

as in the embodiment illustrated in FIG.

3

.

Impact absorbing mechanism

80

with cushioning members

82

, as depicted in

FIG. 4

, are somewhat similar to the embodiment of cushioning members

50

illustrated in FIG.

2

. Like the embodiment depicted in

FIG. 2

, arms

84

or base

92

of cushioning members

82

have different sized openings

88

formed therein and form a plurality of portions in cushioning members

82

having differing cushioning properties. Openings

88

are differently sized and as a result arms

84

each have differing amounts of stiffness. As shown, one of arms

84

of cushioning members

82

does not have an opening

88

formed therein which further changes the stiffness of that arm

84

. What is important is that each arm

84

have a discrete and differing amount of flexibility and deflection in response to a user exercising on belt

32

as a result of the differing stiffness. Cushioning members

82

, consequently, will provide a differing amount of cushioning depending on which of arms

84

is in contact with deck

40

.

Impact absorbing mechanism

80

also comprises an elongated lever

90

, as shown in phantom in

FIG. 4

, configured to manually adjust cushion members

82

. Lever

90

is one embodiment of structure capable of performing the function of selectively adjusting cushioning members

82

so as to selectively select one of the plurality of portions of cushioning members

82

between frame

24

and deck

40

.

FIG. 5

illustrates another embodiment of an impact absorbing mechanism

250

that comprises cushioning members

252

. Like the cushioning members depicted in

FIGS. 1-4

, cushioning members

252

are movably attached to frame

24

and are disposed substantially perpendicular to deck

40

. Cushioning members

252

comprise a plurality of portions having different cushioning properties. Cushioning members

252

comprise a substantially fan-shaped base

254

having different flattened surfaces

255

extending around the rim

253

of base

254

.

Base

254

of cushioning members

252

has different sized openings

256

formed therein, forming a plurality of portions in cushioning members

252

having differing cushioning properties. Openings

256

are differently sized and as a result, different portions of base

254

have differing stiffness. As shown, one of the portions

258

of cushioning members

252

does not have an opening

256

formed therein. This further changes the stiffness of that portion

258

. What is important is that each portion have a discrete and differing amount of flexibility and deflection in response to a user exercising on belt

32

as a result of the differing stiffness. Cushioning members

252

, consequently, will provide a differing amount of cushioning depending on which portion contacts deck

40

.

Impact absorbing mechanism

250

also comprises a hub

260

coupling base

254

to axle

54

. Hub

260

includes fingers

262

(shown in phantom lines) extending radially from a hub sleeve

264

disposed about axle

54

and coupled to axle

54

through the use of a screw (not shown) disposed through sleeve

264

and axle

54

. In one embodiment, base

254

comprises a flexible polyvinylchloride material which is molded onto a nylon or glass-filled nylon hub

260

. By way of example, the polyvinylchloride material may have a durometer of about 65, shore A.

In one embodiment, impact absorbing mechanism

250

is positioned toward the front end

20

of base

12

, e.g., within the front one-third of base

12

. This positioning is particularly useful when the front end

20

of deck

40

is not secured to frame

24

, e.g., when the back end

22

of deck is secured to frame

24

(through the use of screws, for example), while the front end

20

moves freely from frame

24

. Allowing front end

20

to freely deflect from frame

24

enhances the ability to adjust the amount of cushioning applied to deck

40

. In one such embodiment, front end

20

of deck

40

also rests on at least one additional cushioned member such as an isolator coupled to each side of frame

24

, such as discussed below with reference to FIG.

11

.

FIGS. 6

a

-

6

c

illustrate another embodiment of an impact absorbing mechanism

270

that comprises cushioning members

272

. Cushioning members

272

are movably attached to frame

24

and are disposed substantially perpendicular to deck

40

. Cushioning members

272

comprise a plurality of portions having different cushioning properties. Each cushioning member

272

comprises a substantially fan-shaped base

274

having a plurality of recesses

275

extending around the rim

273

of base

274

.

Base

274

of cushioning member

272

comprises a flexible portion

277

attached through adhesion or molding to a substantially more rigid portion

276

, forming a plurality of portions in cushioning members

272

having differing cushioning properties. As a result, different portions of base

274

have differing stiffness. Cushioning members

272

, consequently, will provide a differing amount of cushioning depending on which portion contacts a wheel pivotally coupled to deck

40

, as discussed below.

Impact absorbing mechanism

270

also comprises a hub

280

coupling base

274

to axle

54

. Hub

280

comprises a hub sleeve

282

coupled to base

274

. In one embodiment, hub sleeve

282

is integrally coupled to member

276

and to a plate

271

, such that flexible portion

277

is cradled within plate

271

, hub

280

and member

276

.

Hub sleeve

282

is disposed about axle

54

and coupled to axle

54

through the use of a screw (not shown) disposed through sleeve

282

and axle

54

, for example. In one embodiment, flexible portion

277

comprises a flexible polyvinylchloride material which is molded onto a significantly more rigid nylon or glass-filled nylon member

276

and plate

271

. Hub

280

may also comprise nylon or glass-filled nylon. By way of example, the polyvinylchloride material

277

may have a durometer of about 55, shore A.

Impact absorbing mechanism

270

further comprises a wheel

288

rotatably coupled to deck

40

. In one embodiment, bracket

290

couples wheel

288

to deck

40

. Wheel

288

is configured to mate with a selected recess

275

on cushioning member

272

. Wheel

288

turns as cushioning member

272

turns. This assists in preserving the material of cushioning member

272

from damage as member

272

is turned. Stops

292

coupled to bracket

290

prevent the overrotation of cushioning member

272

.

As yet another feature of impact absorbing mechanism

270

, as shown in

FIG. 6

b

, axle

54

includes a tab

294

coupled to axle

54

. In a preferred embodiment, a motor, such as an extension motor, has an arm

293

thereof pivotally coupled to tab

294

. Upon actuating the motor, such as by pressing a button coupled to the console of the treadmill, the motor rotates the axle

54

. The button and motor pivotally coupled to axle

54

serve as another example of a structure capable of performing the function of selectively adjusting cushioning members

272

so as to select one of the plurality of portions of cushioning members

272

between frame

24

and deck

40

.

In one embodiment, impact absorbing mechanism

250

is positioned toward the front end

20

of base

12

, e.g., within the front one-third of base

12

. One or both of front and back ends

20

,

22

of deck

40

are secured to frame

24

.

As shown in

FIG. 6

c

, in one embodiment, rigid portion

276

comprises a rim

269

having a T-shaped member

279

extending therefrom. Member

279

is covered by flexible portion

277

and enhances the adhesion of flexible portion

277

to the more rigid portion

276

.

FIGS. 7 and 8

depicts treadmill

10

with another embodiment of an impact absorbing mechanism

100

configured for manual adjustment to provide selectable amounts of impact cushioning when a user is operating on exercise section

38

of belt

32

. Impact absorbing mechanism

100

comprises cushioning members

102

. As shown in

FIG. 8

, cushioning members

102

are substantially parallel to deck

40

and are at least partially disposed between deck

40

and frame

24

. Cushioning members

102

can be movably attached to either deck

40

or frame

24

. As depicted in

FIG. 8

, cushioning members

102

are rotatably attached to deck

40

by a vertical axle

108

.

Right frame member

26

and left frame member (not shown) of frame

24

have raised portion

104

formed thereon. Raised portions

104

extend upwardly towards deck

40

and contact cushioning members

102

. Cushioning members

102

illustrated in

FIGS. 7 and 8

have substantially the same configuration as cushioning members

50

depicted in

FIGS. 1 and 2

. Cushioning members

102

comprise a plurality of portions having different cushioning properties. Cushioning members

102

comprise a base

112

with a plurality of openings

52

formed therein. Bases

112

of cushioning members

102

are shown as round, but it is intended, particularly in this embodiment, that cushioning members

102

may have various other shapes without effecting the function thereof. Cushioning members

102

may be square, rectangular, oval, or various other configurations.

As depicted in

FIG. 7

, treadmill

10

has a knob

110

on console

117

that causes cushioning members

102

to be selectively adjusted according to the desired amount of cushioning. Knob

110

on console

117

is one embodiment of structure capable of performing the function of a means for selectively adjusting cushioning members

102

to provide differing amount of impact cushioning. Various other embodiments of structure capable of performing the function of such a means for selectively adjusting members

102

including those disclosed with other embodiments of cushioning members, are equally effective.

Impact absorbing mechanism

100

also comprises a linkage or a cable

106

, shown in

FIG. 7

, configured to mechanically interconnect cushioning members

102

such that movement of one cushioning member

102

results in corresponding movement of other cushioning members

102

. Various embodiments of structure capable of performing the function of such means for mechanically interconnecting cushioning members

102

, including those disclosed with other embodiments of cushioning members, are equally effective. For example, horizontal axle

54

can be mechanically interconnected with vertical axles

108

of cushioning members

102

such that movement of one of cushioning members

102

results in corresponding movement of other cushioning members

102

.

Although bases

112

of cushioning members

102

are depicted as having various sized openings

52

formed therein, other embodiments of cushioning members

102

perform the function thereof equally effectively. For example, instead of openings

52

formed in bases

112

of cushioning members

102

, raised pads comprising materials with different cushioning properties can be mounted on cushioning members

102

. Cushioning members

102

can be selectively adjusted such that the raised pads mounted on cushioning members

102

are selectively positioned on raised portion

104

. In addition, instead of cushioning members

102

being pivotally mounted below deck

40

, cushioning members

102

can be movably attached to frame

24

by vertical axles.

Another embodiment of an impact absorbing mechanism

120

is depicted in FIG.

9

. Impact absorbing mechanism

120

comprises cushioning members

122

attached to opposite sides of frame

24

. Cushioning members

122

are elongated and in the embodiment shown in

FIG. 9

are substantially curved. Various other configurations, however, perform the function thereof equally effectively. For example, cushioning members

122

can be rectangular, square, semispherical, half an oval, half-an-ellipse, or semicircular. As illustrated, cushioning members

122

comprise bases

30

that have a plurality of raised pads

124

mounted thereon. Raised pads

124

each comprise a material with different cushioning properties. The arrangement of raised pads

124

on cushioning members

122

on side one is in an inverse mirror image cushioning members

122

on the opposite side of frame

24

as will be discussed in more detail below.

Impact absorbing mechanisms

120

also comprise an elongated beam

126

movably mounted below deck

40

. Beam

126

extends across frame

24

and is substantially parallel to deck

40

. A portion of beam

126

is disposed between deck

40

and cushioning members

122

to contact the various raised pads

124

. Beam

126

is pivotally connected to deck

40

. Raised pads

124

are arranged on cushioning members

122

so that beam

126

is pivoted to contact one type of raised pad

124

on cushioning members

122

and the opposite end of beam

126

contacts the same material on the opposite of cushioning members

122

as illustrated in FIG.

9

.

Beam

126

is another embodiment of structure capable of performing the function of such means for mechanically interconnecting the plurality of cushioning members

122

. Beam

126

has an elongated handle

128

attached to one end thereof for the user to grasp to selectively, manually adjust the amount of cushioning provided by cushioning members

122

. A user of treadmill

10

can move beam

126

by moving handle

128

until beam

126

contacts the selected raised pads

124

to obtain differing amounts of cushioning of the impact.

FIG. 9

illustrates in phantom an example of another position of beam

126

for a differing amount of cushioning. Handle

128

extends away from beam

126

above frame

24

. Handle

128

is one example of structure capable of performing the function of means for selectively positioning one of the plurality of portions of cushioning members

122

.

Cushioning members

50

,

68

,

82

,

102

and

122

are one embodiment of structure capable of performing the function of impact absorbing means for selectively adjusting the cushioning impact between deck

40

and frame

24

.

FIG. 10

illustrates another embodiment of impact absorbing mechanism

140

that comprises a plurality of flexible cantilevers

142

. Cantilevers

142

comprise a support

144

attached to the inside surface of frame

24

and extends in a direction away from frame

24

. Cantilevers

142

comprise an elongated flexible arm

146

that is attached at one end to support

144

. Arm

146

extends toward front end

20

of frame

24

. Arm

146

has an opposite end that is freely disposed from support

144

and frame

24

. Cantilevers

142

also comprise a bumper

148

mounted on the free end of arm

146

. Bumper

148

extends away from free end of arm

146

toward deck

40

in a direction that is substantially perpendicular to deck

140

.

Impact absorbing mechanism

140

includes an elongated brace

150

that is configured to manually adjust the flexibility of cantilevers

142

. Brace

150

is mounted to frame

24

adjacent to cantilevers

142

. Brace

150

extends substantially perpendicular to the longitudinal axis of frame

24

and is configured to cooperate with frame

24

and to move parallel to the longitudinal axis of frame

24

. As depicted in

FIG. 10

, frame

24

has elongated slots

152

formed therein to accommodate movement of brace

150

, which is selectively movable along the longitudinal axis of frame

24

and the length of cantilever

142

to change in the amount of cushioning provided by cantilevers

142

by increasing or decreasing the amount of deflection of arm

146

in response to a user operating on the exercise section

38

of belt

32

. For example, if brace

150

is moved along the length of cantilevers

142

towards bumper

148

on arm

146

, the amount of deflection or amount of cushioning is decreased. In contrast, if brace

150

is moved towards support

144

, the amount of deflection will increase which consequently results in the amount of cushioning provided to the user increasing.

Various other configurations of brace

150

and slots

152

perform the function thereof equally effectively as long as brace

150

and slots

152

are configured to cooperate together. Brace

150

and slots

152

in frame

24

are one example of structure capable of performing the function of an adjustment means for selectively adjusting the flexibility of cantilever

142

.

FIG. 11

illustrates yet another embodiment of an impact absorbing mechanism

160

that comprises a plurality of flexible cantilevers

162

, only one of which is shown in FIG.

11

. Cantilever

162

comprises a support

164

attached to the inside surface of frame

24

, such as a cross beam. Cantilever

162

further comprises an elongated arm

166

, such as a steel or other metal arm that is attached at one end to support

164

. Arm

166

extends toward front end

20

of frame

24

. Arm

166

has an opposite end that is freely disposed from support

164

and frame

24

.

Cantilever

162

also comprises a bumper

168

mounted on the free end of arm

166

. Bumper

168

extends away from the free end of arm

166

toward deck

40

in a direction that is substantially perpendicular to deck

40

. As another example of a cantilever, another elongated arm and a bumper attached thereto (not shown) extends from an opposing end of support

164

in parallel relationship to the cantilever

162

shown in FIG.

11

. In one embodiment, bumper

168

is positioned toward the front end

20

of base

12

, e.g., within the front one-third of base

12

.

Impact absorbing mechanism

160

further includes an elongated brace

170

that is configured to manually adjust the flexibility of cantilevers

162

. Brace

170

is mounted to frame

24

adjacent to cantilevers

162

. Brace

170

extends substantially perpendicular to the longitudinal axis of frame

24

and is configured to cooperate with frame

24

and to move parallel to the longitudinal axis of frame

24

.

As depicted in

FIG. 11

, frame

24

has elongated slots

172

formed therein to accommodate movement of brace

170

. A second slot is not shown in

FIG. 11

, but is preferably on an opposing side of frame

24

from slot

172

for receiving an opposing end of brace

170

from that shown in FIG.

11

. Brace

170

is selectively movable along the longitudinal axis of frame

24

within opposing slots

172

and along the length of opposing cantilevers

162

to change the amount of cushioning provided by cantilevers

162

by increasing or decreasing the amount of deflection of arms

166

in response to a user operating on the exercise section

38

of belt

32

. For example, if brace

170

is moved along the length of cantilever

162

towards bumper

168

on arm

166

, the amount of deflection or amount of cushioning is decreased. In contrast, if brace

170

is moved towards support

164

, the amount of deflection will increase which consequently results in the amount of cushioning provided to the user increasing.

Also as shown in

FIG. 11

, in one embodiment, each of the opposing slots

172

have teeth

174

therein for selectively receiving gears

176

coupled to opposing ends of brace

170

. Teeth

174

and gears

176

allow convenient adjustment of brace

170

within slots

172

and assist in maintaining brace

170

in a desired orientation within slots

172

during an exercise routine. By moving brace

170

forward and backward within opposing slots

172

, each of the opposing cantilevers

162

is adjusted, preferably achieving an equal degree of deflection.

Various other configurations of brace

170

and slots

172

perform the function thereof equally effectively as long as brace

170

and slots

172

are configured to cooperate together. Brace

170

and slots

172

in frame

24

are one example of structure capable of performing the function of an adjustment means for selectively adjusting the flexibility of cantilever

162

.

As mentioned above, in one embodiment, front end

20

of deck

40

is not secured to frame

24

. Instead, back end

22

of deck

40

is secured to frame

24

(through the use of screws, for example), while front end

20

moves freely from frame

24

, enhancing the ability to adjust the amount of cushioning applied to front end

20

of deck

40

.

In one such embodiment, at least one and preferably both sides of front end

20

of deck

40

also rest on a cushioned isolator

180

, shown in

FIG. 11

, without being coupled to the isolator

180

. However, in another embodiment, front end

20

and back end

22

of deck

40

are both coupled to frame

24

through the use of screws, for example. The screws may be disposed through the deck, the frame, and an isolator, such as isolator

180

disposed between the frame and the deck, for example.

Another example of an impact absorbing mechanism

200

that comprises a plurality of flexible cantilevers

202

,

204

is shown in FIG.

12

. Cantilevers

202

,

204

comprise a support

205

attached to frame

24

diagonally with respect to the longitudinal axis of frame

24

. Cantilevers

202

,

204

further comprise respective elongated arms

206

,

208

attached to opposing ends of diagonal support

205

. Bumpers

207

,

209

are coupled to free ends of respective arms

206

,

208

below deck

40

. Bumpers

207

,

209

extend upwardly with respect to respective arms

206

,

208

and intersect deck

40

. As shown, bumpers

207

,

209

and arms

206

,

208

of respective cantilevers

202

,

204

are oriented in opposing directions.

Impact absorbing mechanism

200

further includes an elongated brace

210

that is configured to manually adjust the flexibility of cantilevers

202

,

204

. Brace

210

is mounted to frame

24

by being pivotally coupled to support

205

. Brace

210

has opposing ends which are disposed beneath respective arms

206

,

208

. Frame

24

has elongated slots

212

,

214

formed therein on opposing sides to accommodate pivotal movement of the ends of brace

210

. Brace

210

moves along the length of opposing cantilevers

202

,

204

to change in the amount of cushioning provided by cantilevers

202

,

204

by increasing or decreasing the amount of deflection of arms

202

,

204

. One advantage of mechanism

200

is that the amount of cushioning provided is adjustable by pivoting brace

210

in a desired direction.

Brace

210

and slots

212

,

214

in frame

24

are one example of structure capable of performing the function of an adjustment means for selectively adjusting the flexibility of cantilevers

202

,

204

.

It can be appreciated by those skilled in the art that although the various embodiments illustrated in the figures usually have two (2) cushioning members or two (2) cantilevers, any other number of a plurality of cushioning members or cantilevers can be used in treadmill

10

.

Although not shown in the figures, it is contemplated that treadmill

10

(

FIG. 1

) includes structure such as a drive means for supplying power to exercise base

12

to drive continuous belt

32

. The drive means for supplying power to base frame

12

is disposed in front end

20

of exercise base

12

. One embodiment of structure capable of performing the function of such a drive means comprises a motor that rotates a first pulley and drives a belt. The belt drives a second pulley which is connected to front roller

34

about which belt

32

is disposed. As previously stated, the rear portion of belt

32

is also disposed around rear roller

36

. Other embodiments capable of performing the function of such a drive means may include a flywheel. The flywheel is connected to belt

32

and receives energy from the user operating on belt

32

of exercise base

12

. The flywheel also delivers energy to belt

32

as the user performs walking, running or jogging exercises when a user is suspended and not in contact with belt

32

.

FIGS. 13-16

b

depict an alternate treadmill

310

with another embodiment of an impact absorbing mechanism

300

configured for selective adjustment to provide selectable amounts of impact cushioning when a user is operating on exercise section

338

of belt

332

.

Treadmill

310

comprises an exercise base

304

comprising: (i) frame

324

, which can be the same or similar to the frame

24

of

FIGS. 1 and 7

; (ii) endless belt

332

trained about front and rear rollers coupled between opposing ends of right and left frame members

325

,

326

(FIG.

15

), such as discussed regarding belt

38

of

FIGS. 1 and 7

; (iii) a deck

340

(

FIGS. 14-15

) coupled to frame

324

, such as discussed regarding deck

40

of

FIGS. 1 and 7

; and (iv) impact absorbing mechanism

300

at least partially disposed between deck

340

and frame

324

. A support structure

306

is coupled to base

304

(e.g., rotatably coupled to the base

304

such that the base

304

can be selectively oriented in an operational position, as shown in

FIG. 13

, or an upright storage position).

Impact absorbing mechanism

300

, which is another example of an impact absorbing means, comprises first and second cushioning members

302

(

FIGS. 14-15

) on opposing sides of treadmill

310

. Cushioning members

302

are substantially parallel to deck

340

and are at least partially disposed between deck

340

and frame

324

. While cushioning members

302

can be movably attached to either deck

340

or frame

324

, in the embodiment of

FIG. 14

cushioning members

302

are rotatably attached to deck

340

by a vertical axle

308

, such that frame

324

of treadmill is contacted by downwardly extending cushioning members

302

.

Member

302

has a plurality of portions, each of which have different cushioning properties, as will be discussed in detail below. To adjust the degree of cushioning, the user causes at least one and preferably both cushioning members

302

to rotate horizontally such that the desired cushioning portion is positioned between the treadmill deck

340

and frame

324

.

As shown in

FIGS. 14-16

b

, cushioning members

302

each comprise a base

312

with a plurality of arms

302

a-c

projecting therefrom. Arms

302

a-c

, each have different cushioning properties. Thus, cushioning members

302

each have a plurality of cushioning portions, namely arms

302

a-c

, each having different cushioning properties. Members

302

each have a generally triangular shape. However, it is intended that the cushioning members that rotate horizontally to adjust the degree of cushioning may have various other shapes without effecting the function thereof, such as square, rectangular, oval, propeller shaped, or various other configurations.

In order to selectively lock a desired arm

302

a-c

into a desired position, a spring loaded ball detent

318

(

FIG. 14

) engages one of three recessed areas

320

a-c

(

FIG. 15

) on the top surface of cushioning member

302

, depending upon the degree of cushioning selected by the user. The recessed areas

320

a-c

are positioned so as to selectively engage the detent

318

and thereby hold the desired respective arm

302

a-c

in place between deck

340

and frame

324

. The same result may be achieved by placing a detent in cushioning member

302

which could engage one of a number of different recessed areas in deck

340

or frame

324

. Alternatively, the detent can be molded as part of cushioning member

302

.

Differing degrees of cushioning can be achieved in cushioning members

302

by (i) providing cushioning portions comprising differing materials; (ii) providing cushioning portions having differing levels of flexibility; (iii) providing cushioning portions having different sizes and/or (iv) providing cushioning portions that are more hollow than others, for example. Thus, a variety of different methods of manufacture may be employed to form each member

302

.

In the embodiment of

FIGS. 14-16

b

, each member

302

is formed by forming a frame

314

configured to hold a plurality of cushioning pads

316

a-c

therein. Each arm portion

302

a-c

comprises (i) a respective frame portion

317

a-c

; and (ii) a respective pad

316

a-c

coupled to a respective frame portion

317

a-c.

In the embodiment of

FIGS. 13-16

b

, frame

314

comprises a rigid or semi-rigid material, while cushioning pads

316

a-c

each comprise a more flexible material that is coupled onto frame

314

, e.g., through molding. Thus, frame

314

may comprise a material that is more rigid than pads

316

a-c

for example. In one embodiment, frame

314

is molded, after which pads

316

a-c

are molded thereon. By way of example, the frame and/or pad portions of cushioning members

302

can be formed from SANTOPRENE, PVC, thermoplastic elastomer, foam and/or other suitable material. For example, in one embodiment the frame

314

and pads

316

a-c

each comprise a SANTOPRENE material, but have different degrees of flexibility.

Frame

314

is configured to receive different pads therein, the pads being shown in a bottom view in

FIG. 14

, and in a cutaway top view in

FIG. 16

a

. A bottom view of the frame is shown without the pads in

FIG. 16

b.

In the embodiment of

FIGS. 16

a-b

, cushioning frame

314

comprises a first frame portion

317

a

, a second frame portion

317

b

, and a third frame portion

317

c

. First and second frame portions

317

a-b

essentially have large apertures therethrough, such that a significant amount of space is available for corresponding pad material

316

a-b

. Third frame portion

317

c

comprises more frame material and has less space therein for the corresponding pad material

316

c.

Since arm

302

c

comprises a substantial amount of rigid or semi-rigid frame material

317

c

and a reduced amount of flexible pad material

316

c

, arm

302

c

is more rigid than arms

302

a

and

302

b

. The pad material

316

a

of arm

302

a

has a large groove therein, whereas the pad material

316

b

of arm

302

b

is solid. Thus, arm

302

a

is more flexible than arm

302

b.

In summary, arm

302

c

comprises less pad material

316

c

and more frame material

317

c

than arm

302

b

, and is consequently more rigid than arm

302

b

. Arm

302

a

has a pad

316

a

having a substantial groove therein, and is consequently more flexible than arm

302

b

. Thus, arm

302

c

is more rigid than arm

302

b

, which is more rigid than arm

302

a

. In light of the different properties of the respective arms, a user desiring different cushioning properties for treadmill

310

can select a desired level of cushioning.

Nevertheless, although arms

302

a-c

of cushioning members

302

are depicted as having raised pad portions formed thereon that have different internal configurations, other embodiments of cushioning members perform the function thereof, such as by employing pad portions having different sizes or different densities. In addition, instead of cushioning members

302

being pivotally mounted below deck

340

, cushioning members

302

can be movably attached to frame

324

by vertical axles.

Indicia, such as the numbers 1, 2, and 3 (or other indicia, such as lettering, color coding, providing other symbols, etc.) may be provided on the frame and/or pads of member

302

to allow a user to visually determine which amount of cushioning has been selected. For example, in the embodiment of

FIG. 16

a

, the numeral “1” corresponds to the most flexible amount of cushioning (arm

302

a

), the numeral “2” corresponds to an intermediate amount of flexibility (arm

302

b

), and the numeral “3” corresponds to the most rigid amount of cushioning (arm

302

c

).

Thus, as shown in the embodiment of

FIG. 15

, a user desiring an intermediate level of cushioning can move cushioning members

302

until the number 2 or other indicia appears on the edge of the treadmill of FIG.

15

. In this embodiment, arms

302

b

of members

302

are mounted between frame

324

and deck

340

to thereby provide an intermediate level of flexibility to treadmill

310

.

Gripping grooves

322

on members

302

allow a user to conveniently grip a selected member

320

. Thus, members

302

can be selectively adjusted according to the desired amount of cushioning by gripping the gripping grooves

320

and rotating a selected member

302

in a horizontal plane. Such grooves

320

are one embodiment of structure capable of performing the function of a means for selectively adjusting cushioning members

302

to provide differing amounts of impact cushioning. Various other embodiments of structure capable of performing the function of such a means for selectively adjusting members

302

may be employed.

Impact absorbing mechanism

300

may further comprise a linkage or a cable (not shown), (e.g., similar to element

106

shown in FIG.

7

), configured to mechanically interconnect cushioning members

302

such that movement of one cushioning member

302

results in corresponding movement of other cushioning members

302

. Various embodiments of structure capable of performing the function of such means for mechanically interconnecting cushioning members

302

, including those disclosed above with other embodiments of cushioning members, are equally effective. For example, each cushioning member

302

can be configured with a gear thereon. A chain can link the gears such that movement of one of cushioning members

302

results in corresponding movement of other cushioning members

302

.

As shown in

FIG. 15

, frame

324

includes right and left frame members

325

,

326

, such as discussed with reference to base

12

of FIG.

1

. Front and back rollers are attached laterally between respective front and back ends of frame members

325

,

326

and an endless belt

332

is trained over the front and back rollers. A right side rail

342

is shown mounted on deck

340

. Optionally, a left side rail may also be mounted on deck

340

.

Deck

340

may be mounted on frame

324

in a variety of different manners, such as those discussed above with regard to deck

40

and frame

24

. In one embodiment, the rear portion of the deck is immovably affixed to rear portions of opposing frame members

325

,

326

while the front portion of the deck

340

is coupled to the front portions of opposing frame members

325

,

326

through the use of elastomeric isolators coupled between the deck and the frame that allow some deflection between the deck

340

and the frame

324

during use.

FIG. 17

provides a view of an alternate treadmill embodiment of the present invention, wherein first and second frame members

324

a

(only one frame member shown) are positioned below deck

340

a

in such as manner that the frame members

324

a

are inwardly disposed with respect to the sides of deck

340

a

. In this embodiment, the indicia (e.g., the numeral “2”) on the cushioning member

302

is viewed by a user through the use of an aperture

341

through deck

340

a

through which the user can view the numeral. A corresponding aperture

341

also exists in the side deck rails

342

a

, which are mounted on the sides of deck

340

a

adjacent the treadmill belt

338

a

. Thus, in one embodiment, the deck

340

a

and side deck rail

342

a

of the present invention each have an aperture

341

therethrough such that the user can see through the deck

340

a

and rail

342

a

to view the indicia (e.g., the numeral “2”) on respective members

302

on opposing sides of the deck

340

a

. One or both sides of deck

340

a

and one or both corresponding deck rails may have an aperture

341

therethrough corresponding to one or more respective cushioning members

302

.

FIG. 18

provides a top view of an alternate cushioning member

350

of FIG.

17

. As illustrated, the cushioning member

350

includes a base

351

having a plurality of arms

352

a-c

radially extending therefrom. Each of the cushioning arms

352

a-c

have different cushioning properties to allow a user to selectively adjust the amount of cushioning provided. The difference in cushioning may be achieved through the use of material having different densities, different configurations, different sizes, by hollowing on or more portions, or through the use of stiffer materials surrounded by different amounts of padded material, for example. In one embodiment, arm

352

b

is denser, and consequently more stiff, than arm

352

a

and less dense and stiff than arm

352

c

. In yet another embodiment the pad on an intermediate level cushioning arm is larger than the least cushioned arm and smaller than the most cushioned arm. In yet another embodiment, an arm having a hollow or grooved pad, an arm having a solid pad, and an arm comprising more frame material than the other arms, as discussed with reference to member

302

, are employed. Indicia, e.g., numerals corresponding to the differences in flexibility are shown in phantom lines. These indicia appear on the top portions of arms

352

a-c.

Thus, an example of another cushioning mechanism of the present invention comprises first and second cushioning members, configured such as member

350

, on opposing sides of a treadmill between the deck and the frame thereof. However, optionally member

350

may be employed on a single side to form a cushioning mechanism.

As illustrated in

FIG. 19

, the cushioning member

350

is coupled between frame

324

a

and deck

340

a

, such as through the use of a vertical axle. Deck rail

342

is also shown. In the embodiment of

FIG. 19

, the deck rail

342

and deck

340

a

each have an aperture

341

therethrough that allows the user to visually inspect the corresponding indicia, e.g., numeral, to thereby determine the amount of cushioning selected by the user. The deck rail

342

of

FIG. 19

has an integral tubular sleeve

358

that fits downwardly within the aperture in deck

340

a

to thereby enhance the aesthetic appearance of the aperture in deck

340

a

. By viewing through the sleeve

358

, the user can see what level of cushioning has been selected. Optionally, a glass or plastic window may be placed in the aperture in the deck and/or rail. The deck rail(s)

342

a

discussed with respect to

FIG. 17

may optionally employ the sleeve

358

shown in FIG.

19

.

Thus, in order to view the indicia indicating the level of cushioning employed, the cushioning portions with the indicia thereon may extend out from the area directly between deck and the frame such that the indicia is visible to the user, or an aperture through the deck may be employed. Each of these approaches are examples of means for enabling a user to view the level of cushioning employed.

FIG. 20

depicts an alternate embodiment of an adjustable cushioning mechanism

400

for use in an exercise device, such as a treadmill. Cushioning mechanism

400

comprises a spring

402

and a screw

404

threadedly mounted within the spring

402

. Spring

402

is coupled between treadmill deck

406

and treadmill frame

408

. An aperture

412

extends through frame

408

(or optionally, in another embodiment, through the deck) and receives screw

404

therethrough. The interior of spring

402

is configured to correspond to the threads

410

of screw

404

and to allow screw

404

to be threaded therethrough in a helical fashion.

As screw

404

extends into spring

402

, the amount of cushioning is adjusted. The extension into or extraction from spring

402

, respectively, decreases or increases the ability of the spring

402

to cushion. In other words, the movement of screw

404

with respect to spring

402

selectively increases or decreases the effective length of spring

402

.

Thus, as screw

404

is threaded out of spring

402

, the effective length of spring

402

is increased and the degree of flexibility increases; and as screw

404

is threaded into spring

402

, the effective length of spring

402

is decreased and the degree of flexibility decreases.

In the embodiment of

FIG. 20

, the treadmill frame

408

is raised off the support surface sufficiently enough that the user can place his/her hand under frame

408

, grip a knob

414

of screw

404

, and selectively thread screw

404

into spring

402

or out of spring

402

to thereby adjust the amount of flexibility achieved. The space between the support surface and knob

414

allows the user to rotate knob

414

. Alternatively, screw

404

is coupled to an adjustment mechanism that includes a motor to selectively adjust the cushioning by threading the screw.

Spring

402

may be coupled between deck

406

and frame

408

in a variety of different manners. For example, in one embodiment, the ends of the deck and the frame are coupled together in such a manner as to maintain spring

402

therebetween. In another embodiment, one or both ends of the spring are embedded into a corresponding deck or frame portion. For example, one end (e.g., the top end) of the spring may be embedded in the deck or frame while the opposing portion of the spring is not embedded but rests against the opposing frame or deck portion. In another embodiment, a screw extends from the deck or frame (or both) and connects with the corresponding end (e.g., the top end) of the spring. In yet another embodiment, the opposing ends of the spring are captured within cups (i.e., surrounded by the rims of the cups) mounted on respective portions of the deck and frame. One or both cups may have an aperture therethrough in order to allow the screw to extend therethrough.

In another embodiment, frame

408

is internally threaded so as to threadedly receive screw

404

therein. In this embodiment, screw

404

is threadedly received within frame

408

and spring

402

. By way of example, screw

404

may comprise an elastomeric, plastic, or similar material, although a variety of different materials may be employed.

Thus, the present invention relates to treadmills with an impact absorbing mechanism that is configured to selectively adjust the cushioning of a user's impact.

The present invention may be embodied in other specific forms without departing from its spirit or essential characteristics. The described embodiments are to be considered in all respects only as illustrative and not restrictive. The scope of the invention is, therefore, indicated by the appended claims rather than by the foregoing description. All changes which come within the meaning and range of equivalency of the claims are to be embraced within their scope.

Number	Name	Date	Kind
3592466	Parsons	Jul 1971	A
3689066	Hagen	Sep 1972	A
4350336	Hanford	Sep 1982	A
4509510	Hook	Apr 1985	A
4548405	Lee et al.	Oct 1985	A
4576376	Miller	Mar 1986	A
4616822	Trulaske et al.	Oct 1986	A
4819583	Guerra	Apr 1989	A
4886266	Trulaske	Dec 1989	A
4938473	Lee et al.	Jul 1990	A
4984810	Stearns et al.	Jan 1991	A
5072928	Stearns et al.	Dec 1991	A
5088729	Dalebout	Feb 1992	A
5184988	Dunham	Feb 1993	A
5250012	Meredith	Oct 1993	A
5279528	Dalebout et al.	Jan 1994	A
5330401	Walstead	Jul 1994	A
5336144	Rodden	Aug 1994	A
5344372	Hung	Sep 1994	A
5374227	Webb	Dec 1994	A
5382207	Skowronski et al.	Jan 1995	A
5441468	Deckers et al.	Aug 1995	A
5454772	Rodden	Oct 1995	A
5476430	Lee et al.	Dec 1995	A
5484362	Skowronski et al.	Jan 1996	A
5518471	Hettinger et al.	May 1996	A
5527245	Dalebout et al.	Jun 1996	A
5542892	Buhler	Aug 1996	A
5599259	Skowronski et al.	Feb 1997	A
5626539	Piaget et al.	May 1997	A
5634870	Wilkinson	Jun 1997	A
5649882	Parikh et al.	Jul 1997	A
5690587	Gruenangerl	Nov 1997	A
5749807	Webb	May 1998	A
5752897	Skowronski et al.	May 1998	A
5810696	Webb	Sep 1998	A
5827155	Jensen et al.	Oct 1998	A
5976061	Moon et al.	Nov 1999	A
5980432	Ahman	Nov 1999	A
5993358	Gureghian et al.	Nov 1999	A
6013011	Moore et al.	Jan 2000	A
6045490	Shafer et al.	Apr 2000	A
6050921	Wang	Apr 2000	A
6053848	Eschenbach	Apr 2000	A
6068578	Wang	May 2000	A
6095951	Skowronski et al.	Aug 2000	A
6132340	Wang et al.	Oct 2000	A
6174267	Dalebout et al.	Jan 2001	B1
6174268	Novak	Jan 2001	B1
6179753	Barker et al.	Jan 2001	B1
6234936	Wang	May 2001	B1
6280362	Dalebout et al.	Aug 2001	B1
6328676	Alessandri	Dec 2001	B1
6394239	Carlson	May 2002	B1
6436008	Skowronski et al.	Aug 2002	B1

	Number	Date	Country
Parent	09/437387	Nov 1999	US
Child	09/777141		US

	Number	Date	Country
Parent	09/777141	Feb 2001	US
Child	09/953589		US

Treadmill with adjustable cushioning members

Information

Patent Number

Date Filed

Date Issued

Inventors

Original Assignees

Examiners

Agents

CPC

US Classifications

Field of Search

US

International Classifications

Term Extension

Abstract

Description

Claims

RELATED APPLICATIONS

US Referenced Citations (55)

Non-Patent Literature Citations (4)

Continuations (1)

Continuation in Parts (1)

Entry
Kutz, M., ed., Mechanical Engineer's Handbook, 2nd ed., New York: John Wiley & Son Inc., 1998.
Hibbeler, R.C., Engineering Mechanics Statics, 4th ed., New York: Macmillan Publishing Company, 1986.
Precor USA M9.3 Low Impact Treadmill Brochure, Copyright 1990.
U.S. Patent Application Publication, Publication No. US 2002/0010055 A1, Publication Date: Jan. 24, 2002, Inventors: Dyer et al.