JPH11319144A - Suspension device for body training system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To satisfactorily absorb shocks in a simple configuration independent of the weight of an exercising person. SOLUTION: This device has a frame 12, first and second roller assemblies 14 and 16 mounted onto the frame 12, an endless belt 18 wound around the first and second roller assemblies, a deck 20 arranged between the frame and the upper running part of the endless belt while having first and second terminal parts, a rotating connector for linking the second terminal part of the deck to the frame so as to freely turn it around an axis almost orthogonal to the length of the deck, and at least one long spring arranged between the frame and the deck while being located between the first and second terminal parts of the deck. The spring supports the deck together with the rotating connector and absorbs shocks applied to the deck by the exercising person.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a body training apparatus, and more particularly to a body training treadmill, and more particularly to a suspension apparatus for supporting a treadmill deck above a lying frame structure. is there.

[0002]

2. Description of the Related Art Treadmills for physical training are widely used in recreational facilities, sports clubs, and private homes, and are capable of walking, jogging, and running indoors. Treadmills are particularly useful in bad weather or at night or in other cases where the athlete does not want to run outdoors. Many treadmills have a first roller assembly and a second roller assembly mounted orthogonally on opposite ends of the frame. An endless belt is wound around the roller assembly. The upper run of the belt is located between the belt and the frame and is supported by a lying deck.

[0003] Various efforts have been made in the past to reduce the impact on the legs and joints of the user when jogging or running on the treadmill. One way to reduce the impact on an athlete's body is in U.S. Pat.
Nos. 4,974,831 and 4,984,810. In the treadmills disclosed in these patents, the rear end of the deck is mounted rotatably with respect to the frame,
The front end of the deck is supported by a suspension device. In the '831 patent, the suspension system consists of a rather complex lever arm system and a cooperating shock absorber. The stride on the deck rotates the lever arm and extends the shock absorber, thereby damping the impact of the user's foot. The disadvantage of this shock absorber lies in its own complexity, which increases the manufacturing costs.

[0004] In the '810 patent, the forward end of the dreadmill deck is a shock absorber separate from the conventional compression spring.
Supported by Placing springs and shock absorbers at the forefront of the deck imposes non-negligible bending stress on the deck.

[0005] Other conventional treadmills have a rubber block located between the deck and the lying frame to absorb impact. Such a conventional treadmill is disclosed in French Patent No. 2,616,132. The dreadmill deck is located above the frame members and on a plurality of flexible pads. A bush is inserted above and below each pad, and a bolt hanging downward from the deck and a bolt extending upward from the frame are received by the corresponding bush. The bolt absorbs shock by placing a flexible pad between the deck and the frame.

US Pat. Nos. 5,336,144 and 5,454,772
No. 4,087,064 discloses a deck supported above the frame by a plurality of cup-shaped elastomer springs. The elastomer spring reversibly deforms as the deck flexes downward relative to the frame. The elastomer spring has a tapered side wall.
As a result, the resistance of the elastomer spring to downward movement of the deck is proportional to the degree of deflection of the deck relative to the frame. One disadvantage of such treadmills is that the elastomer springs are fixed in place, each defining a smaller bearing area.

[0007]

SUMMARY OF THE INVENTION An object of the present invention is to improve the suspension structure of a conventional treadmill for body training as described above.

[0008]

In order to achieve the above object, a treadmill adopted by the present invention comprises a frame, a first roller assembly and a second roller mounted on the frame. A roller assembly and an endless belt wound around the first and second roller assemblies. The treadmill further includes a deck disposed between the frame and the upper run of the endless belt and having a first end and a second end. Also provided is a rotatable connection for rotatably connecting the second end of the deck to the frame. An elongate elastomeric spring member is disposed between the frame and the deck and between the first and second ends of the deck and spaced above the frame. We support deck which we established with. As the athlete steps on the endless belt, the elastomeric spring member is reversibly deformed to resist deflection (downward movement) of the deck relative to the frame. The resistance provided by the elastomer-spring member is proportional to the degree of deflection of the deck.

In another aspect of the invention, an elastomer spring member is provided between the side rails of the frame and below the side edges of the deck.

In another aspect of the present invention, an elastomer spring has a base portion and a bulging body extending upwardly from the base portion. The main body is formed in a hemispherical or convex shape, and has a shape bulging outward at the top. The interior of the elastomer spring between the base and the body is hollow or partially hollow. As a result, the body will flex downwards due to the force the exerciser imposes on the deck.

In still another aspect of the present invention, the thickness of the main body of the elastomer spring is larger at the connection with the base. The thickness of the main body is made thinner as it goes away from the base, and becomes thinnest at the top of the hemispherical main body. As a result, if the deck applies a downward load on the elastomeric spring, the top center of the body will deflect downwardly into the hollow interior. With the present invention, there is no lateral deformation that would occur if the elastomeric spring were stripped. Also, the resistance imposed on the deck by the elastomer springs increases as the deck is deformed downward, thus providing a variable spring rate.

[0012] In another aspect of the invention, the spring is configured such that the rate of deformation can be selectively varied. In this context, the shape and dimensions of the compressible insert are determined such that they can be selectively inserted to the desired extent of the hollow part of the spring. In cross-section, the insertion member corresponds to the cross-sectional shape of the hollow portion of the spring. The spring may be tapered in its length direction. In another aspect, the body of the spring is configured to receive a compressible fluid as a bladder. Specifically, the compressible fluid comprises air, which is supplied to the bag by an air pump. Also, valves or other means are provided for discharging the compressible fluid from the bladder.

In still another aspect of the present invention, the pivot connection at the rear end of the deck is mounted on a side member of the frame.
It has a spindle connected to a hinge bracket provided on the lower side of the deck. With this configuration, the rear end of the deck is mounted rotatably with respect to the frame about an axis extending perpendicularly to the length of the deck.

[0014]

1, a treadmill 10 constructed in accordance with the present invention has a frame 12, on which a forward roller is traversed. An assembly 14 and a rear roller assembly 16 are provided. As used herein, forward means the direction in which the athlete goes when using the treadmill. Also,
"Forward" and "rearward" are used to mean opposite directions. An endless belt 18 is wound between the front roller assembly 14 and the rear roller assembly 16. A deck 20 is provided between the upper running portion of the belt 18 and the frame 12.

As shown in FIG. 2, FIG. 3, and FIG.
The rear portion of the deck is pivotally mounted to the frame by a pivot connection 24 so that the rear portion of the deck is rotated about an axis extending with respect to the length of the deck so as to be orthogonal to the frame. It can move. An elongate, deformable spring 26 is provided on the frame and supports the deck together with the pivot connection 24 by lying below the side edges of the deck.

More specifically, the frame 12 has a pair of elongated side rails 30a and 30b.
The reference numerals a and 30b are disposed in parallel by a rear-side horizontal member 32, an intermediate horizontal member 34, and a front-side horizontal member 36 with a space therebetween in the horizontal direction. Preferably, the cross members are formed from a hollow extruded metal, so that a high strength to weight ratio can be obtained. Side lay
A plurality of brackets 38 are disposed on the rollers 30a and 30b, and engage with the ends of the roller bodies 14 and 16 as shown in FIGS.

Further, the frame 12 has a pair of plate-like mounting plates 40a and 40b which are located between the intermediate horizontal member 34 and the front horizontal member 36 and extend upward and upward. And supports the post 40 extending upward. The post 40 extends upward and forward from the front end of the frame 12 and has a handrail 4.
4 is supported. The handrail 44 extends rearward and slightly downward from the lateral portion 42 and extends downward, and its extended end is attached to the frame by a mounting bracket 46. The handrail is designed to be grasped by a hand when the exerciser walks, jogs, or runs on the treadmill 10.

The post 40 supports a display panel 41. The display panel 41 has a belt speed, exercise length, calorie consumption, exercise course, and the like during use of the treadmill. Various information is displayed. Typically, the display panel is provided with various control knobs or buttons, such as a start button, speed control, emergency stop, and the like.

The treadmill 10 further has a motor 50, and a drive shaft 52 of the motor is connected to a drive belt 54 provided at one end of the front roller assembly 14. The motor 50 is rotatably mounted on the front roller assembly 14.
To move the treadmill belt 18,
The exerciser stride on the belt. The motor 50 is disposed in a housing cover 56 extending across the front of the treadmill.

2 to 4, side rails 30 are shown.
a and 30b are mirror images of each other,
It is understood that the parts denoted by the same reference numerals in these figures are the same kind of parts. As shown in FIG. 4, each of the side rails 30a and 30b is formed of a metal extruded material having a plurality of hollow portions, and has an outer portion 60 and an inner portion 62, and these portions are substantially upright. Share the extension wall 64. In the cross section, both the outer portion 60 and the inner portion 62 form a closed box portion, but the outer portion 60 has a slightly more complicated shape than the inner portion 62. The outer portion 60 has an outer wall 66 that is curved to project outwardly, and the outer wall 66 extends downward from the upper lip 68 toward the lower horizontal wall 70. Located between the upper lip 68 and the lower horizontal wall 70, the outer wall has an inwardly extending groove 72, which has an inlet 74 that is slightly narrower than the height of the groove itself. I have. Groove 72
Are dimensioned to slidably receive an inner key (not shown) of a bracket 46 for mounting the lower end of the handrail 44 to the side rail of the frame.

Referring further to FIG. 4, the inner portion 62 includes a substantially horizontal upper wall 76, a substantially vertical inner wall 78, and a substantially horizontal lower wall 80. Which, in cooperation with the common wall 64, define a closed, substantially rectangular box-shaped cross-section. As shown in FIG. 3, the rear side member 32 supports the bottom of the lower wall 80. Further, the lower edge of the intermediate cross member 34 is substantially flush with the upper wall 76. As shown in FIGS. 2 and 3, a bracket 38 used for mounting the front roller assembly 14 and the rear roller assembly 16 is disposed on the upper wall 76. Functions as a shoulder. Further, an elongated elastomer spring 26 is mounted on the upper wall 76. The side rails 30a and 30b are not limited to those shown in the drawings, but may have other structures without departing from the spirit of the present invention.

In FIGS. 2 and 3, the deck 20 is formed of a flat, square and sufficiently strong panel, and the panel has smooth upper and lower surfaces. Suitable materials for forming the deck include plywood, other stiffened plate structures, reinforced thermoset plastic materials, metals, and other sufficiently strong members. Preferably, the deck strength is E
I [elastic modulus (lb / in ² ) X inertia moment (i
n ⁴ )] is approximately 0.5 × 10 ⁶ to 2.0 × 10 ⁶ lb
in ² range. Preferably, the upper surface of the deck is coated or embedded with a low friction coating, such as a wax compound.

As shown in FIG. 5, a trim stripe 84 is formed on each side edge of the deck to protect the end portion of the deck and restrain the belt 20 in the lateral direction. The trim stripe 84 has an upper portion 86 that overlaps the top of the side edges of the deck, a side 88 that supports the side edges of the deck, and a lower shoulder 9 that overlaps the lower edge of the deck.
0. Preferably, trim stripe 84 is formed from an extruded metal member or plastic material.

Still referring to FIG. 5, the pivot connections 24 are located at the respective ends of the rear portion of the deck, thereby providing the rear portion of the deck with the inner portion 62 of the side rail of the frame. And has two hinge assemblies adapted to be mounted on the shaft 94 so as to be rotatable with respect to an orthogonal shaft 94. More specifically, each hinge assembly has a mounting spindle 96 secured to the inner surface of frame wall 78. A flanged bearing 98 is provided on the reduced diameter shoulder formed at the distal end of the spindle 96, and the flange bearing web is mounted in a circular opening formed below the vertical leg 102 of the hinge bracket 104. ing. The hinge bracket 104 has a horizontal upper mounting plate portion 106, which is provided with a clearance opening, extends through the deck, and extends under the plate portion 106 to form a lower portion.
A screw member connected to the wear member 108 is received.

The means for rotatably mounting the rear portion of the deck 20 with respect to the frame 12 may be other means. For example, a piano hinge (not shown) may be placed below the deck 20 and attached to a frame horizontal member (not shown).

In particular, in FIG. 4, the spring 26 is shown as having a generally "d" shaped cross section. The spring 26 has a base portion 11 lying on the upper frame wall 76.
2 and 3 has a protruding or dome-shaped main body 114 which protrudes upward in a bulging shape.
As shown in FIG. 5, the main body 114 extends upward from the base portion and supports the side edge of the deck 20 from below. The interior 116 of the spring 26 is preferably hollow or substantially hollow to allow downward deformation of the body 114. Preferably, body portion 114 is not formed of a uniform thickness, but rather is configured such that its thickness decreases with increasing distance from base portion 112, and that the thickness of the top of the dome of body 114 is increased. Is set to a thickness of about 1/3 to 1/2 of the thickness of the main body at the connection portion with the base portion 112.

The performance of the spring 26 can be changed by changing its cross-sectional dimension. Increasing the overall cross-sectional dimension of the spring 26 and the size of the spring 26 can provide a stiffer spring, or decreasing the size can provide a less stiff spring. Also, the performance of the spring can be changed or altered by changing the thickness of various parts of the main body.

In one preferred embodiment, the width of the spring is about 1.0 to 1.5 inches and the base 112
Has a thickness of about 0.2 to 0.4 inches. Also, the overall height of the spring is about 1 to 1.25 inches.
Further, the thickness of the main body portion is 0.3 to 0.4 inches at the connection portion with the base portion, and the thickness decreases upward, and the thickness of the top portion of the main body portion is about 0. .1 to 0.2 inches. Note that these dimensions are only examples and do not limit the scope of the present invention.

Preferably, the spring 26 is made of an elastomeric material such as a natural rubber or a synthetic rubber compound. The spring 26 is changed by changing the strength of the rubber.
You can also change the spring rate and other performance of the. The spring 26 is also formed to a length selected depending on the degree to which the spring 26 resists downward deformation.

The spring 26 is connected to the side rail 30.
a, disposed at a site selected along the length of 30b;
A condition is obtained in which the deck 26 responds to the impact load imposed by the athlete. Preferably, the springs 26 are positioned along the side rails to coincide with where the athlete's feet strike the belt on the deck 20.

The spring 26 is held in position by a long piece 120 extending through a long groove formed in the base 112 of the spring. Both ends of the long piece 120 project from both ends of the elastomer spring to form tabs provided with clearance holes, and penetrate downwardly to the inside of the rail wall 76. An extended screw member is received. Incidentally, other means for mounting the spring 26 on the frame rail may be employed.

As described above, the spring 26 is flared.
Selective positioning along the length of the mulleles can alter the energy absorption and cushioning effects provided by the elastomeric spring. This can be done by simply loosening the screw member 122 and reconnecting the screw member 122 within the wall 76 at different locations along the frame rail.

Although the spring 26 is shown mounted on the frame side rail, it may be mounted on the lower surface of the deck 20 instead. For example, it can be performed by connecting the screw member 122 upward to the inside of the lower surface of the deck 20.

The spring 26 may be configured to be slidable along the frame rail. For example, as shown in FIG. 6, the upper wall 76 'of the frame rail is formed in the groove 130 having an open shape upward to form the spring 26'.
It can be done by accepting. 6 that are the same as those in FIGS. 1 to 5 are denoted by the same reference numerals, but the prime reference numeral “′” is used.
Is attached. Any suitable means may be employed to hold the spring 26 'in the longitudinal direction of the groove 130.

When the treadmill according to the present invention is used, the deck flexes (moves) downward toward the frame 12 when the athlete's feet are placed on the belt 18. This deflection is counteracted by the compression of the spring 26. The spring 26 functions to absorb the impact of the exerciser's foot. The deck of the treadmill is rotatably mounted at a rear portion thereof, and the other portions are supported only by springs.
Can freely move up and down (rotation). The downward deflection of deck 20 toward frame 12 results in reversible compression of spring 26. In particular, the center of the top of the spring body 114 is smaller in thickness than the portion where the body is connected to the base 112, so that the center is first deformed downward. However, as the deck 20 continues to move downward toward the frame 12, the gradually thicker portion of the body 114 is also compressed and deformed. Thus, the springs 26 become increasingly stiff with further compression, providing a degree of resistance to downward movement of the deck 20 that increases in proportion to the range of movement of the deck 20.

Further, the main body 114 of the elastic spring is thinnest at the top of the main body. As a result, the body 114 does not deform laterally as it deforms (which would place a lateral load on the deck 20), but instead has its central portion facing downwards It is designed to be deformed. This lateral or lateral deformation tendency can be prevented by making the body portion 114 gradually thinner from the base portion 112 toward the top of the bulging portion.

The degree of resistance to downward movement of the deck 20 provided by the springs 26 is proportional to the flexing or downward movement of the deck 20, so that the treadmill 1
0 provides adequate shock absorption for exercisers of all weights. Lighter athletes do not exert as much impact on the treadmill when stepping down. However, the treadmill deck 20 deforms downwardly toward the frame due to the relatively easy compression of the initial spring 26 ', thus providing adequate shock absorption even for relatively light individuals. be able to. When a heavier individual uses a treadmill, a greater impact is applied to the deck 20, but this load is borne by the resistance of the spring 26, which increases as the downward deformation of the deck 20 increases. become.

The embodiment of the present invention shown in FIGS. 7 and 8 relates to a spring assembly 132 composed of a bulged or hollow spring 26 '' constructed similarly to the springs 26 and 26 '. is there. The spring assembly 132 includes an insertion member 13 shaped and sized to be received within the hollow interior 116 '' of the spring 26 ''.
Four. Preferably, but not necessarily, the outer shape of the insert 134 is generally
This corresponds to the shape of the 6 ″ hollow interior 116 ″.
Also, ideally, the length of the insert 134 corresponds to a significant portion of the length of the hollow interior 116 '' of the spring 26 ''. The spring 26 ″ and the insert 134 cooperate to form a spring assembly 132 to support the deck 20.

The purpose of the insert 134 is to change the performance of the spring assembly 132. For this reason, the insertion member 134 can be composed of a member similar to or different from the member forming the spring 26 ''. For example, the insert member 134 may be a hard material, a soft material, a more elastic material,
It is composed of a more inelastic material. Further, the material of the insertion member may be solid, hollow, or partially hollow, depending on the desired rigidity and flexibility for forming the insertion member. The selection of a particular material compound or configuration for the insert 134 provides for the desired overall performance of the spring assembly 132 in cooperation with the spring 26 ''.

In addition to the material from which the insert 134 is constructed, the performance of the spring assembly 132 can be altered by altering the extent to which the insert 134 connects within the spring 26 ''. Preferably, as shown in FIG.
The device 136 selectively connects the inside of the spring 26 ″ and separates from the outside of the spring 26 ″. The actuator device 136 has a power actuator 138, which is connected to the connection shaft 142 through the adjacent end wall 140 of the insertion member 134. Various types of actuators 138 are employed, for example, linear push-pull actuators such as fluid cylinders and magnetic coil assemblies. Alternatively, for example, the actuator 138 may be a rotary type driven by an electric rotary motor. In this example,
The connecting shaft 142 is a lead screw that is screwed into the end wall 140. The actuator 138 is a display panel 41
May be remotely operated by the user by using a control button or other interface device provided in the system.

Further, as shown in FIG.
Is tapered in its length direction so as to form a different gap 144 between the top of the insertion member 134 and the underside of the spring 26 ''. This configuration allows the spring 26 "to be deformable downward at a specific spring rate, which increases when the top wall of the spring 26" is sufficiently deformed to abut the top of the insert 134. become. With this configuration, the spring assembly 132 initially provides a relatively low level of resistance to downward movement of the deck 20 ″, and once the spring 26 ″ deforms sufficiently to eliminate the gap 144, the deck assembly Provide a relatively high level of resistance to further downward movement of the

FIGS. 9 to 11 show another embodiment of the present invention.
In this case, the spring 26 "" is dimensioned to be received in an upwardly open groove 130 "" formed in the upper wall 76 "" of the frame rail. This is the fluid bag that has been applied. As shown in FIG.
6 '''is adapted to press against the lower surface of the deck 20''', thereby supporting the deck. Although the bag has an elliptical cross-sectional shape as illustrated, it may have another cross-sectional shape such as a circle, a square, or a rectangle.

A compressible fluid, such as air, is supplied to the supply hose 15 connected to an inlet formed in the bag 26 '''.
0 to the bag 26 ″ ′. When air is used as the compressible fluid, the air compressor 154 is used as a supply source. The compressible fluid is discharged out of the bladder 26 '''through a discharge valve 156 in fluid communication with the bladder. Also, valve 156 may be in fluid communication with supply hose 150, or may be incorporated into the configuration of compressor 154. The stiffness of the bag 26 '''depends on the pressure of the compressible fluid, which can be remotely controlled by push buttons 158, 160 arranged on the display panel 41.

Instead of using two bags 26 "" provided on the side rails of the frame, one bag 2 provided on the horizontal member 162 of the frame as shown in FIG.
6 ″ ′ may be adopted. The cross members may be stationary with respect to the frame or may be positionally adjustable along the length of the frame so that the position supported by the bag 26 ''' You may make it changeable in a length direction. Incidentally, the bag body 26 '''may be replaced with a spring assembly 132 mounted on the horizontal member 162.

As described above or as shown in FIG.
6, 26 ', 26 ", 26"' are formed in an elongated shape and the spring is located between the frame and the deck, so that a sufficient interface length between the spring and the deck is provided. In other words, the area or area can be obtained, and the holding stress or the contact stress can be reduced or minimized. At the same time, there is no need to increase the height in the vertical direction, so that the spring can be installed easily and easily. Also, the spring according to the invention has a reduced number of parts, which leads to manufacturing, assembly, installation, management and reliability.

[Brief description of the drawings]

FIG. 1 is a perspective view of a treadmill for body training according to the present invention.

FIG. 2 shows the frame, deck and treadmill of FIG.
It is a disassembled perspective view which shows a rotation connection and an elastic spring.

FIG. 3 is a sectional view showing a part of the tread mill shown in FIG. 1;

FIG. 4 is a partial perspective view showing an enlarged frame of a treadmill at a portion of an elastic spring.

FIG. 5 is a partially enlarged perspective view showing a pivotal connection between the deck and the frame.

FIG. 6 is a partially enlarged cross-sectional view according to another embodiment.

FIG. 7 is an enlarged elevational view according to another embodiment.

FIG. 8 is a sectional view taken along line 8-8 in FIG. 7;

FIG. 9 is an enlarged elevation view according to another embodiment.

FIG. 10 is a sectional view taken along line 10-10 in FIG. 9;

FIG. 11 is an exploded perspective view according to another embodiment.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 Treadmill 14 Roller assembly 16 Roller assembly 18 Endless belt 20 Deck 24 Rotating connection 26 Elongated spring

 ────────────────────────────────────────────────── ─── Continued on the front page (72) Inventor Thomas Moran, Seattle, WA, USA 29th Avenue West 3607 (72) Inventor Jenny Wonton, United States Woodinville, Washington 147s Place N. A-. 14931

Claims (80)

[Claims] (A) a frame; (b) a first roller assembly and a second roller assembly mounted on the frame; and (c) the first and second rollers. An endless belt wound around the roller assembly; and (d) a first end and a second end disposed between the frame and an upper running portion of the endless belt. (E) a pivotal connection for pivotally coupling the second end of the deck to the frame for rotation about an axis substantially perpendicular to the length of the deck. (F) disposed between the frame and the deck and between the first end and the second end of the deck to absorb the load applied to the deck by the athlete; At least one elongate spring having a length substantially parallel to the plane of the deck. Treadmill for physical culture characterized. 2. The spring according to claim 1, wherein the spring is a frame.
A treadmill, which is disposed between the wheel and the lower surface of the deck. 3. The treadmill according to claim 2, wherein the spring is disposed in a longitudinal direction of the deck. 4. The treadmill according to claim 2, wherein the spring is disposed so as to be orthogonal to the length of the deck. 5. The frame according to claim 1, wherein said frame has a pair of side rails spaced apart in a lateral direction, and said spring is disposed between each side rail and said deck. A treadmill, which is provided. 6. The tread mill according to claim 5, wherein said spring is disposed between the side rail and a lower surface of the deck. 7. A tread mill according to claim 6, wherein said spring is disposed in a longitudinal direction of the side rail. 8. The frame according to claim 5, wherein the frame is a side lay.
A treadmill having at least one transverse member that crosses between the rails, wherein a spring is disposed between the transverse member and the lower surface of the deck. 9. The tread mill according to claim 8, wherein the spring is disposed in a longitudinal direction of the horizontal member. 10. The invention of claim 1 wherein the spring provides resistance to movement of the deck toward the frame under a load imposed by an athlete, in proportion to the amount of movement of the deck toward the frame. Treadmill characterized by the following. 11. The treadmill according to claim 1, wherein the spring has a variable spring rate, and the spring rate increases with deformation of the spring. 12. The treadmill according to claim 11, wherein the spring is made of an elastomer material. 13. The treadmill according to claim 1, wherein the spring rate of the spring is adjustable. 14. The treadmill according to claim 13, wherein the spring is formed of an elastomer member. 15. The treadmill according to claim 1, wherein the spring is reversibly deformable under a load on the deck by an exerciser. 16. The treadmill according to claim 15, wherein a deformation range of the spring at a unit load imposed by the deck decreases as the load imposed on the elastomer spring increases. 17. The treadmill according to claim 16, wherein the spring is formed of an elastomer member. 18. The treadmill according to claim 1, wherein the spring is at least partially hollow. 19. The spring according to claim 18, wherein the spring is a base.
A treadmill comprising an elastomer member having a base portion and a deformable convex portion extending from the base portion. 20. The tread mill according to claim 19, wherein the thickness of the convex portion of the elastomer spring decreases in the direction away from the base portion. 21. The treadmill according to claim 19, wherein the elastomer spring has means for attaching a base portion of the spring to the frame. 22. The convex-shaped deformable portion according to claim 19, wherein at least a part of the convex-shaped deformable portion is formed in a hollow shape, and further has a size and a shape that can be selectively inserted to a desired degree into the hollow portion of the convex portion. A treadmill having a configured compressible insert. 23. The tread mill according to claim 22, wherein the cross-sectional shape of the insertion member substantially corresponds to the shape of the hollow portion inside the convexly deformable portion. 24. The treadmill according to claim 22, wherein the insertion member is tapered in a length direction. 25. The treadmill according to claim 22, further comprising means for changing a range of contact of the insertion member in the spring. 26. The treadmill according to claim 22, wherein the insertion member is formed of an elastomer member. 27. The bag of claim 18, wherein the spring is configured to receive a compressible fluid, means for supplying the bag with compressible fluid, and means for removing the compressible fluid from the bag. And a treadmill comprising: 28. A tread mill according to claim 27, wherein the compressible fluid is air and an air pump for introducing air into the bag is provided. 29. The treadmill according to claim 27, wherein the frame has a recess for receiving the bag. 30. The treadmill according to claim 1, further comprising mounting means for mounting a spring on the frame at a selected position in the longitudinal direction of the deck. 31. A pivot connection according to claim 1, wherein the pivot connection is provided between a spindle provided on one frame and the second end of the deck, and a hinge provided on the other frame and the second end of the deck. A treadmill comprising a bracket and a treadmill. 32. The treadmill according to claim 1, wherein the deck is substantially rigid. 33. The deck according to claim 32, wherein the deck has an EI value of 0.5 × 10 ⁶ to 2.0 × 10 ⁶ lb. A treadmill having a strength in the range of ² in. 34. (a) a frame; (b) a first roller assembly and a second roller assembly mounted on the frame; and (c) the first and second rollers. An endless belt wound around the roller assembly; and (d) a first end and a second end disposed between the frame and an upper running portion of the endless belt. (E) a pivot for pivotally connecting the second end of the deck to the frame so as to pivot about an axis substantially perpendicular to the length of the frame; And (f) at least one elongated spring disposed between the frame and the deck and between the first end and the second end of the deck; The spring supports the deck with respect to the frame, absorbs the load applied to the deck by the athlete, and Treadmill for physical culture, characterized in that so as to resist movement of the deck towards the arm - frame when stepping the. 35. The frame according to claim 34, wherein the frame includes a pair of elongated side rails which are arranged laterally at intervals from each other by a plurality of horizontal members, and the springs are provided on the respective side rails. A treadmill, which is located between the bottom of the deck and the underside of the deck. 36. The treadmill according to claim 34, wherein the spring is reversibly deformable under a load on the deck by an exerciser. 37. The treadmill of claim 36, wherein the spring provides a resistance to movement of the deck relative to the frame at a level proportional to the extent to which the deck moves toward the frame. 38. The treadmill according to claim 37, wherein a rate of reversible deformation of the spring is inversely proportional to a degree of deformation of the spring. 39. The treadmill according to claim 38, wherein the spring is formed of an elastomer member. 40. The treadmill according to claim 34, wherein the spring rate of the spring is adjustable. 41. The bag of claim 41, wherein the spring is configured to receive a compressible fluid, means for supplying the bag with compressible fluid, and means for removing the compressible fluid from the bag. And a treadmill comprising: 42. The tread mill according to claim 41, wherein the frame has a concave portion for receiving the bag, and assists in positioning the bag with respect to the frame. 43. The treadmill according to claim 34, wherein the spring is at least partially hollow. 44. The method according to claim 43, wherein the spring is a base.
A treadmill comprising an elastic member having a base portion and an outwardly projecting convex body extending from the base portion. 45. The treadmill according to claim 44, wherein the bulging body of the spring is formed of an elastomer material. 46. The tread mill according to claim 44, wherein the thickness of the bulging body is reduced in a direction away from the base portion. 47. The treadmill according to claim 44, further comprising means for mounting a spring at a selected position in a length direction of the side rail. 48. The treadmill according to claim 43, further comprising a compressible insertion member sized and shaped to be inserted into the hollow portion of the spring to a selected extent. 49. The spring according to claim 48, wherein the spring has a hollow portion along a substantial part of its length,
A treadmill, wherein the length of the insertion member is at least half the length of the hollow portion. 50. The treadmill according to claim 48, wherein the insertion member is tapered along its length. 51. The treadmill according to claim 48, further comprising means for gradually inserting the insertion member into the spring and pulling out the insertion member from the spring. 52. The invention of claim 34, wherein the pivoting connection includes hinge means for frame mounting the second end of the deck, the second end extending generally perpendicular to the length of the deck. A treadmill characterized by rotating about an axis. 53. A hinge device according to claim 52, wherein said hinge means is provided on a spindle provided at an orthogonal rotation axis of said hinge means, connected to said spindle, and mounted on one of said second end portions of said deck and said frame. A treadmill having a hinged bracket. 54. (a) a frame; (b) a first roller assembly and a second roller assembly mounted on the frame; and (c) the first and second rollers. An endless belt wound around the roller assembly; and (d) a first end and a second end disposed between the frame and an upper running portion of the endless belt. And (e) disposed between the frame and the deck and between the first end and the second end of the deck to absorb a load applied to the deck by an exerciser. And (f) means for selectively changing the spring rate of the spring. 55. The treadmill according to claim 54, wherein the spring is disposed between the frame and the lower side of the deck. 56. The treadmill according to claim 55, wherein the spring is disposed substantially along the length of the deck. 57. The treadmill according to claim 55, wherein the spring is disposed substantially perpendicular to the length direction of the deck. 58. The frame according to claim 54, wherein the frame has a pair of side rails spaced apart in the lateral direction, and the spring is disposed between each side rail and the deck. Treadmill. 59. The treadmill according to claim 58, wherein the spring is disposed between the side rail and the lower side of the deck. 60. The treadmill according to claim 59, wherein the spring is disposed in a length direction of the side rail. 61. The frame according to claim 58, wherein the frame has at least one cross member extending between the side rails, and the spring is disposed between the cross member and the lower side of the deck. And a treadmill. 62. The treadmill according to claim 61, wherein the spring is disposed in a longitudinal direction of the horizontal member. 63. In claim 54, the spring provides resistance to movement of the deck relative to the frame under a load imposed by the athlete, proportional to the extent to which the deck moves toward the frame. Treadmill characterized by the following. 64. The treadmill according to claim 54, wherein the spring rate increases with deformation of the spring. 65. The treadmill according to claim 64, wherein the spring is made of an elastomer material. 66. The treadmill according to claim 54, wherein the spring is reversibly deformable under a load on the deck by an exerciser. 67. The treadmill according to claim 66, wherein the deformation range of the spring at a unit load imposed by the deck decreases as the load imposed on the elastomer spring increases. 68. The treadmill according to claim 67, wherein the spring is constituted by an elastomer member. 69. The treadmill according to claim 54, wherein the spring includes a hollow body extending in a longitudinal direction. 70. The treadmill of claim 67, further comprising a compressible insert sized and shaped to be selectively inserted into the hollow portion of the spring to a desired extent. 71. A spring according to claim 70, wherein the spring has a base portion integrally formed with the main body portion.
A treadmill having means for attaching a rim portion to a frame. 72. The tread mill according to claim 70, wherein the cross-sectional shape of the insertion member substantially corresponds to the cross-sectional shape of the hollow portion of the spring. 73. The treadmill according to claim 72, wherein the insertion member is tapered in the length direction. 74. The treadmill according to claim 70, wherein the insertion member is tapered in the length direction. 75. The treadmill according to claim 70, further comprising means for changing a range of connection of the insertion member in the spring. 76. The treadmill according to claim 70, wherein the insertion member is formed from an elastomer member. 77. The bag of claim 69, wherein the spring is configured to receive a compressible fluid, means for supplying the compressible fluid to the bag, and means for removing the compressible fluid from the bag. And a treadmill comprising: 78. The tread mill according to claim 77, wherein the compressible fluid is air and an air pump for introducing air into the bag is provided. 79. The treadmill according to claim 77, wherein the frame has a recess for receiving the bag. 80. The deck of claim 54, wherein the deck has an EI value of from 0.5 × 10 ⁶ to 2.0 × 10 ⁶ lb. in ²
A treadmill having a strength in the range of