JP4065603B2 - Suspension device for body training device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a physical training device, and more particularly to a treadmill for physical training, and more particularly to a suspension device that supports a deck of a treadmill above a lying frame structure.
[0002]
[Prior art]
Treadmills for physical training are widely used in recreational facilities, sports clubs, and individual homes, and can walk, jog, and run indoors. Treadmills are particularly useful when the weather is bad 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 provided orthogonally at both ends of the frame. An endless belt is wound around the roller assembly. An upper running portion of the belt is supported by a lying deck located between the belt and the frame.
[0003]
Conventionally, various efforts have been made to reduce the impact on a user's legs and indirectly when jogging or running on a treadmill. One method for reducing the impact on an exerciser's body is disclosed in US Pat. Nos. 4,974,831 and 4,984,810. In the treadmills disclosed in these patents, the rear end portion of the deck is rotatably attached to the frame, and the front end portion of the deck is supported by the suspension device. In the '831 patent, the suspension system consists of a fairly complex lever arm device and a cooperating shock absorber. The stride on the deck rotates the lever arm and extends the shock absorber, thereby dampening the impact on the user's foot. The disadvantage of this shock absorber is its own complexity, which increases the manufacturing cost.
[0004]
In the '810 patent, the forward end of the dreadmill deck is supported by a shock absorber separate from the conventional compression spring. Placing the spring and shock absorber at the forefront of the deck imposes a non-negligible bending stress on the deck.
[0005]
In other conventional treadmills, a rubber block is disposed between the deck and the lying frame to absorb the impact. Such a conventional treadmill is disclosed in French Patent No. 2,616,132. The dreadmill deck is positioned above the frame member and is provided on the plurality of flexible pads. Bushes are inserted above and below each pad, and bolts hanging downward from the deck and bolts extending upward from the frame are received by the corresponding bushes. The bolt absorbs shock by placing a flexible pad between the deck and the frame.
[0006]
U.S. Pat. Nos. 5,336,144 and 5,454,772 disclose decks supported above the frame by a plurality of cup-shaped elastomer springs. The elastomer spring deforms reversibly when the deck bends downward relative to the frame. The elastomer spring has a side wall having a taper-like thickness. As a result, the resistance to downward movement of the deck by the elastomer spring is proportional to the degree of deflection of the deck relative to the frame. One drawback of such a treadmill is that the elastomer springs are fixed in place, each determining a smaller bearing area.
[0007]
[Problems to be solved by 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]
[Means for Solving the Problems]
In order to achieve the above object, a treadmill adopted by the present invention includes a frame, a first roller assembly and a second roller assembly attached to the frame, and the first and first rollers. And an endless belt wound around the two-roller assembly. The treadmill further includes a deck disposed between the frame and the upper running portion of the endless belt and having a first end and a second end. The deck further includes a pivot connection for pivotally coupling the second end of the deck to the frame. A long elastomer spring member is disposed between the frame and the deck between the first end and the second end of the deck, and is spaced above the frame. Supports the deck that was established. When the athlete steps on the endless belt, the elastomeric spring member deforms reversibly, resisting the 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.
[0009]
In another aspect of the invention, an elastomer spring member is provided between the frame side rails and below the side edges of the deck.
[0010]
In another aspect of the invention, the elastomer spring has a base portion and a bulging body extending upward from the base portion. The main body is formed in a hemispherical shape or a convex shape, and has a shape that bulges outward at the top. The interior of the elastomer spring between the base portion and the main body portion is hollow or partially hollow. As a result, the main body portion is bent downward by the force exerted on the deck by the exerciser.
[0011]
Furthermore, in another aspect of the present invention, the thickness of the body portion of the elastomer spring is greater at the connection portion with the base portion. The thickness of the main body portion is configured to become thinner as the distance from the base portion increases, and is the thinnest at the top of the hemispherical main body portion. As a result, when the deck imposes a downward load on the elastomer spring, the top center portion of the main body is deflected downward into the hollow interior. In the present invention, the lateral deformation that may occur when the elastomer spring is peeled off does not occur. Also, the resistance imposed on the deck by the elastomer spring increases as the deck deforms downward, thus providing a variable spring rate.
[0012]
In another aspect of the invention, the spring is configured such that the deformation rate can be selectively changed. In this connection, the shape and dimensions of the compressible insert are determined so that they can be selectively inserted into the desired extent of the spring cavity. In the cross section, the insertion member corresponds to the cross-sectional shape of the hollow portion of the spring. The spring may have a taper shape in the length direction. In another aspect, the body of the spring is configured to receive a compressible fluid as a bag. Specifically, the compressible fluid is air, and the air is supplied to the bag body by an air pump. A valve or other means is also provided for discharging compressible fluid from the bag.
[0013]
In yet another aspect of the invention, the pivotal connection of the rear end of the deck has a spindle attached to the side member of the frame and connected to a hinge bracket provided on the underside of the deck. With this configuration, the rear end portion of the deck is mounted so as to be rotatable with respect to the frame about an axis extending orthogonal to the length of the deck.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
Referring to FIG. 1, a treadmill 10 constructed in accordance with the present invention has a frame 12 above the frame 12 over the frame 12 and a front roller assembly 14 and a rear roller. An assembly 16 is provided. In the present specification, the front means a direction in which the exerciser heads when using the treadmill. “Front” and “rear” 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 traveling portion of the belt 18 and the frame 12.
[0015]
As shown in FIGS. 2, 3 and 5, the rear part of the deck 20 is pivotally mounted to the frame by a pivot connection 24, and the rear part of the deck extends relative to the length of the deck. It can be rotated around an axis to be orthogonal to the frame. An elongated, deformable spring 26 is provided on the frame and lies under the side edge of the deck to support the deck along with the pivot connection 24.
[0016]
Describing in detail the present invention, the frame 12 has a pair of elongated side rails 30a and 30b. The side rails 30a and 30b include the rear side member 32, the middle. The lateral member 34 and the front lateral member 36 are arranged in parallel with a gap in the lateral direction. Preferably, the cross member is formed from a hollow metal extruded material, so that a high strength with respect to the weight ratio can be obtained. A plurality of brackets 38 are disposed on the side rails 30a and 30b, and engage with the end portions of the roller bodies 14 and 16 as shown in FIGS.
[0017]
Further, the frame 12 has a pair of flat plate-like mounting plates 40a and 40b which are located between the intermediate horizontal member 34 and the front side horizontal member 36 and extend upwardly upward. The post 40 extending upward is supported. The post 40 extends upward and forward from the front end of the frame 12, and supports the lateral portion 42 of the handrail 44. The handrail 44 extends rearward and slightly downward from the lateral portion 42 and extends downward, and the extended end portion is attached to the frame by a mounting bracket 46. The handrail is grasped by a hand when an athlete walks, jogs or runs on the treadmill 10.
[0018]
The post 40 supports a display panel 41. The display panel includes various information during use of the treadmill such as the speed of the belt, the length of the exercise, the calorie consumption, and the exercise course. Is displayed. Typically, the display panel is provided with various control knobs or buttons such as a start button, a speed control, and an emergency stop.
[0019]
The treadmill 10 further has a motor 50, and the motor drive shaft 52 is connected to a drive belt 54 provided on one end side of the front roller assembly 14. The motor 50 is rotatably driven to drive the front roller assembly 14, thereby moving the treadmill belt 18 so that the athlete strides over the belt. The motor 50 is disposed in a housing cover 56 that extends across the front of the treadmill.
[0020]
2 to 4, the side rails 30a and 30b are configured in a mirror image with each other, and it is understood that the parts denoted by the same reference numerals are the same parts. As shown in FIG. 4, the side rails 30a and 30b are made of a metal extruded material having a plurality of hollow portions, and have an outer portion 60 and an inner portion 62, and these portions are generally raised. The extended wall 64 is shared. In the cross section, the outer part 60 and the inner part 62 together form a closed box part, but the outer part 60 has a slightly more complicated shape than the inner part 62. The outer portion 60 has an outer wall 66 that is curved to project outward, 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. Yes. The groove 72 is sized so as to slidably receive an inner key portion (not shown) of the bracket 46 for attaching the lower end portion of the handrail 44 to the side rail of the frame.
[0021]
With further reference to FIG. 4, the inner portion 62 has a substantially horizontal upper wall 76, a substantially vertical inner wall 78, and a substantially horizontal lower wall 80. They cooperate with the common wall 64 to determine a closed, substantially rectangular box-shaped cross section. As shown in FIG. 3, the rear lateral member 32 supports the bottom of the lower wall 80. Further, the lower edge of the intermediate transverse member 34 is substantially flush with the upper wall 76. As shown in FIGS. 2 and 3, the 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, and other configurations can be adopted without departing from the spirit of the present invention.
[0022]
2 and 3, the deck 20 is formed of a flat, square, and sufficiently strong panel, and the panel has a smooth upper surface and lower surface. Suitable materials for forming the deck include plywood, other reinforcing plate structures, reinforced heat-set plastic materials, metals, and other members with sufficient strength. Preferably, the strength of the deck is EI [elastic modulus (lb / in ² ) X inertia moment (in ^Four )] Is approximately 0.5 × 10 ⁶ To 2.0X10 ⁶ lbin ² Range. Preferably, the upper surface of the deck is coated or embedded with a low friction coating such as a wax composite.
[0023]
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 upper side edge of the deck, a side portion 88 that supports the side edge of the deck, and a lower shoulder 90 that overlaps the lower end portion of the deck. Preferably, the trim stripe 84 is formed from an extruded metal member or a plastic material.
[0024]
Further, referring to FIG. 5, the pivot connection 24 is located at each end of the rear part of the deck, so that the rear part of the deck is attached to the inner part 62 of the side rail of the frame. The two hinge assemblies are configured so as to be rotatable with respect to an orthogonal axis 94. More particularly, each hinge assembly has a mounting spindle 96 that is secured to the inner surface of the frame wall 78. A flange bearing 98 is provided on the reduced diameter shoulder portion formed at the end of the spindle 96, and the web portion of the flange bearing is mounted in a circular opening formed at a lower portion of the vertical leg portion 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 a hardware member 108 below the plate portion 106. And a screw member connected to the head.
[0025]
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 under the deck 20 and attached to a frame horizontal member (not shown).
[0026]
In particular, in FIG. 4, the spring 26 is shown as having a generally “d” cross-sectional shape. The spring 26 has a base portion 112 lying on the frame upper wall 76 and a bulging upward projecting shape, and has a convex or dome-shaped main body portion 114. 2 and 3, the main body 114 extends upward from the base portion, and supports the side edge portion of the deck 20 from below. The interior 116 of the spring 26 is preferably hollow or substantially hollow, allowing the body portion 114 to be deformed downward. Preferably, the body portion 114 is not formed from a uniform wall thickness, but rather is configured such that the wall thickness decreases as it moves away from the base portion 112, and the wall thickness at the top of the dome of the body 114 is reduced. Is approximately 1/3 to 1/2 of the thickness of the main body at the connecting portion with the base portion 112.
[0027]
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. Further, the performance of the spring can be changed or altered by changing the thickness at various parts of the main body.
[0028]
In one preferred embodiment, the spring width is about 1.0 to 1.5 inches and the base 112 thickness is about 0.2 to 0.4 inches. 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 connecting portion with the base portion, and the thickness gradually decreases upward, and the thickness of the top portion of the main body portion is about 0. .1 to 0.2 inches. In addition, these dimensions are only examples and do not limit the scope of the present invention.
[0029]
Preferably, the spring 26 is made of an elastomer material such as natural rubber or a synthetic rubber compound. It is also possible to change the spring rate and other performance of the spring 26 by changing the strength of the rubber. The spring 26 is also formed to a length selected according to the degree to counter the downward deformation of the spring.
[0030]
In addition, the spring 26 is disposed at a portion selected along the length of the side rails 30a and 30b so that the deck 26 can react to the impact load imposed by the athlete. Preferably, the springs 26 are disposed along the side rails so that they coincide with the site where the athlete's feet strike the belt on the deck 20.
[0031]
The spring 26 is held in position by a long piece 120 extending through a long groove formed in the base portion 112 of the spring. Both ends of the long piece 120 protrude from both ends of the elastomer spring to form a tab having a clearance hole, and penetrate the tab downward to reach the inside of the rail wall 76. An extending screw member is received. It should be noted that other means may be adopted as means for attaching the spring 26 to the frame rail.
[0032]
As described above, by selectively positioning the spring 26 along the length of the frame rail, it is possible to change the energy absorption and the action effect obtained by the elastomer spring. This can be done by simply loosening the screw member 122 and reconnecting the screw member 122 into the wall 76 at different locations along the frame rail.
[0033]
Although the spring 26 is illustrated as being mounted on the frame side rail, it may be mounted on the lower surface side of the deck 20 instead. For example, it can be performed by connecting the screw member 122 upward in the lower surface of the deck 20.
[0034]
The spring 26 may be configured to be slidable along the frame rail. For example, as shown in FIG. 6, this can be done by forming the upper wall 76 'of the frame rail in an upward groove 130 to receive the spring 26'. 6 that are the same as those in FIG. 1 to FIG. 5 are given the same reference numerals, but are marked with a prime code “′”. Any suitable means may be employed to maintain the position of the spring 26 ′ in the length direction of the groove 130.
[0035]
When the treadmill according to the present invention is used, the deck bends (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 athlete's foot. The treadmill deck is rotatably mounted at the rear part thereof, and the other parts are supported only by the spring, so that the deck 20 freely moves up and down (rotates) with respect to the frame 12. be able to. The downward deflection of the deck 20 toward the frame 12 results in reversible compression of the spring 26. In particular, the center of the top of the spring main body 114 has a smaller wall thickness than the portion where the main body is connected to the base 112, so that the center first deforms downward. However, when the deck 20 continues to move downward toward the frame 12, the portion of the main body 114 that gradually becomes thicker is also compressed and deformed. Thus, the spring 26 becomes progressively stiffer 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.
[0036]
Further, the main body 114 of the elastic spring is thinnest at the top of the main body. As a result, the main body 114 does not deform laterally when deforming (in this case, a lateral load will be applied to the deck 20), but its central portion is directed downward. It is designed to deform. This tendency to deform laterally or laterally can be prevented by forming the main body 114 gradually thinner from the base portion 112 toward the top of the bulging portion.
[0037]
Since the degree of resistance to the downward movement of the deck 20 provided by the spring 26 is proportional to the deflection or downward movement of the deck, the treadmill 10 provides adequate shock absorption for any weight athlete. To do. Lighter weight athletes do not apply much impact to the treadmill when they step down. However, the treadmill deck 20 is deformed downward toward the frame by the compression of the initial spring 26 'which is relatively easy to obtain, thus providing adequate shock absorption even for relatively light individuals. be able to. When a heavier individual uses the 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.
[0038]
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 ″ configured similar to the springs 26 and 26 ′. The spring assembly 132 includes an insert member 134 that is shaped and dimensioned to be received within the hollow interior 116 '' of the spring 26 ''. Preferably, although not necessarily so, the outer shape of the insertion member 134 generally corresponds to the shape of the hollow interior 116 '' of the spring 26 ''. Also, ideally, the length of the insertion member 134 is a length corresponding to an important part of the length of the hollow interior 116 '' of the spring 26 ''. The spring 26 ″ and the insertion member 134 cooperate to form the spring assembly 132 to support the deck 20.
[0039]
The purpose of the insertion member 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 insertion member 134 is made of a hard material, a soft material, a more elastic material, or a more inelastic material with respect to the material constituting the spring 26. Further, the material of the insertion member may be peeled, hollow, or partially hollow, corresponding to the rigidity and flexibility desired for constituting the insertion member. By selecting a particular material compound or configuration of the insert member 134, the desired overall performance of the spring assembly 132 is obtained in cooperation with the spring 26 ''.
[0040]
In addition to the material from which the insert member 134 is constructed, the performance of the spring assembly 132 can also be altered by changing the extent to which the insert member 134 is linked within the spring 26 ''. As shown in FIG. 7, the insertion member 134 is preferably selectively linked within the spring 26 ″ by the actuator device 136 and is detached from the outside of the spring 26 ″. The actuator device 136 has a power actuator 138, and the actuator 138 passes through the adjacent end wall 140 of the insertion member 134 and is connected to the connecting shaft 142. 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 may be remotely controlled by the user by a control button provided on the display panel 41 or other interface device.
[0041]
Further, as shown in FIG. 7, the insertion member 134 has a taper shape in the length direction, and a different gap 144 is formed between the top of the insertion member 134 and the lower surface of the spring 26 ″. ing. This configuration allows the spring 26 '' to be deformed downward at a particular spring rate, which increases when the top wall of the spring 26 '' is sufficiently deformed to abut the top of the insert 134. become. According to this configuration, the spring assembly 132 initially provides a relatively low level of resistance to the downward movement of the deck 20 ″ and once the spring 26 ″ is sufficiently deformed to eliminate the gap 144, the deck Providing a relatively high level of resistance to further downward movement of the.
[0042]
Another embodiment of the present invention is shown in FIGS. 9-11, in which the spring 26 '''opens upwardly formed in the upper wall 76''' of the frame rail. A fluid bag formed into a size that can be received in a groove 130 '''. As shown in FIG. 9, the bag body 26 '''is pressed against the lower surface of the deck 20''', thereby supporting the deck. The bag has an elliptical cross-sectional shape, but may have another cross-sectional shape such as a circle, square, or rectangle.
[0043]
A compressible fluid, such as air, is supplied to the bag body 26 '''via a supply hose 150 connected to an inlet formed in the bag body 26'''. When air is used as the compressible fluid, an air compressor 154 is employed as a supply source. The compressible fluid is discharged out of the bag body 26 '''through a discharge valve 156 in fluid communication with the bag body. Valve 156 may also be in fluid communication with supply hose 150 or may be incorporated into the configuration of compressor 154. The stiffness of the bag body 26 ′ ″ depends on the pressure of the compressible fluid, and this pressure can be remotely controlled by push buttons 158 and 160 disposed on the display panel 41.
[0044]
Instead of using the two bag bodies 26 '''provided on the side rails of the frame, one bag body 26''' provided on the lateral member 162 of the frame is employed as shown in FIG. May be. The transverse member is stationary with respect to the frame or can be adjusted in position along the length of the frame so that the position supported by the bag 26 '''is the position of the deck 20'''. It may be possible to change the length. Note that the bag body 26 ′ ″ may be replaced with a spring assembly 132 mounted on the transverse member 162.
[0045]
As described above or illustrated, the springs 26, 26 ', 26 ", 26'" are formed in an elongated shape, and the spring is positioned between the frame and the deck, so that the spring is positioned between the spring and the deck. Sufficient interface length or area can be obtained, and holding stress or contact stress can be reduced or minimized. At the same time, since it is not necessary to increase the height in the vertical direction, the installation of the spring can be performed well and easily. Also, the spring according to the present invention has a small 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.
2 is an exploded perspective view showing a frame, a deck, a rotating connection, and an elastic spring of the treadmill shown in FIG. 1. FIG.
3 is a cross-sectional view of a part of the treadmill shown in FIG.
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 the 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 elevation view according to another embodiment.
8 is a cross-sectional view taken along line 8-8 in FIG.
FIG. 9 is an enlarged elevation view according to another embodiment.
10 is a cross-sectional view taken along line 10-10 in FIG.
FIG. 11 is an exploded perspective view according to another embodiment.
[Explanation of symbols]
10 Treadmill
14 Roller assembly
16 Roller assembly
18 Endless belt
20 decks
24 Rotating connection
26 Long spring

Claims (53)

(A) a frame;
(B) a first roller assembly and a second roller assembly mounted to the frame;
(C) an endless belt wound around the first and second roller assemblies;
(D) a deck disposed between the frame and the upper running portion of the endless belt, and having a first end portion and a second end portion;
(E) as the second end portion of the deck pivots about an axis generally perpendicular to the length of the deck, a pivot connecting the second end of the deck for rotatably connected with respect to said frame A pivot connection for supporting the second end of the deck so as to pivot in the vertical direction with respect to the frame ;
(F) at least one disposed between the frame and the deck between the first end and the second end of the deck to absorb a load applied to the deck by the athlete. has an elongated spring, and the spring is disposed such that the length is generally parallel to the plane of the deck, the deck is moved vertically relative to the frame by said pivot connection and the spring A treadmill for body training characterized by being supported as possible . 2. The treadmill according to claim 1, wherein the spring is disposed between the frame and the lower surface of the deck. 3. The treadmill according to claim 2, wherein the spring is disposed in a length direction of the deck. 3. The treadmill according to claim 2, wherein the spring is disposed so as to be orthogonal to the length of the deck. 2. The frame according to claim 1, wherein the frame has a pair of side rails arranged in the lateral direction with a space therebetween, and the spring is arranged between each side rail and the deck. treadmill. 6. The treadmill according to claim 5, wherein the spring is disposed between the side rail and the lower surface of the deck. 7. The treadmill according to claim 6, wherein the spring is disposed in a length direction of the side rail. 6. The treadmill according to claim 5, wherein the frame has at least one cross member that crosses between the side rails, and the spring is disposed between the cross member and the lower surface of the deck. 9. The treadmill according to claim 8, wherein the spring is disposed in a length direction of the transverse member. 2. A treadmill according to claim 1, wherein the spring provides resistance to movement of the deck toward the frame under the load imposed by the athlete in proportion to the amount the deck moves toward the frame. 2. The treadmill according to claim 1, wherein the spring has a variable spring rate, and the spring rate increases as the spring is deformed. 12. The treadmill according to claim 11, wherein the spring is made of an elastomer material. The treadmill according to claim 1, wherein the spring rate of the spring is adjustable. The treadmill according to claim 13, wherein the spring is made of an elastomer member. 2. The treadmill according to claim 1, wherein the spring is reversibly deformable under a load applied to the deck by the athlete. 16. The treadmill according to claim 15, wherein the deformation range of the spring in the unit load imposed by the deck decreases as the load imposed on the elastomer spring increases. The treadmill according to claim 16, wherein the spring is made of an elastomer member. 2. The treadmill according to claim 1, wherein the spring is hollow at least partially. The treadmill according to claim 18, wherein the spring is composed of an elastomer member having a base portion and a deformable convex portion extending from the base portion. 20. The treadmill according to claim 19, wherein the thickness of the convex portion of the elastomer spring becomes thinner in a direction away from the base portion. 20. The treadmill according to claim 19, wherein the elastomer spring has means for attaching the base portion of the spring to the frame. 20. The compressible portion according to claim 19, wherein at least a part of the convex deformable portion is formed in a hollow shape, and further, the compressible portion is configured to have a size and a shape that can be selectively inserted into the hollow portion of the convex portion to a desired degree. A treadmill characterized by having an insertion member. 23. The treadmill according to claim 22, wherein a cross-sectional shape of the insertion member substantially corresponds to a shape of a hollow portion inside the convex deformable portion. The treadmill according to claim 22, wherein the insertion member is tapered in the length direction. 23. The treadmill according to claim 22, further comprising means for changing a contact range of the insertion member in the spring. The treadmill according to claim 22, wherein the insertion member is formed of an elastomer member. 19. The spring of claim 18, wherein the spring includes a bag configured to receive the compressible fluid, means for supplying the compressible fluid to the bag, and means for removing the compressible fluid from the bag. A featured treadmill. 28. The treadmill according to claim 27, wherein the compressible fluid is air and has an air pump for introducing air into the bag body. 28. The treadmill according to claim 27, wherein the frame has a recess for receiving the bag. 2. The treadmill according to claim 1, further comprising mounting means for mounting a spring on the frame at a selected position in the length direction of the deck. 2. The pivot connection according to claim 1, wherein the pivot connection includes a spindle provided at one frame and the second end of the deck, and a hinge bracket provided at the other frame and the second end of the deck. Red mill. 2. A treadmill according to claim 1, wherein the deck is substantially rigid. 33. The deck of claim 32, wherein the deck has an EI value of 0.5 × 10 ⁶ to 2.0 × 10 ⁶ lb. A treadmill characterized by having a strength in the range of in ² . (A) a frame;
(B) a first roller assembly and a second roller assembly mounted to the frame;
(C) an endless belt wound around the first and second roller assemblies;
(D) a deck disposed between the frame and the upper running portion of the endless belt, and having a first end portion and a second end portion;
(E) as the second end portion of the deck pivots about an axis generally perpendicular to the length of the deck, a pivot connecting the second end of the deck for rotatably connected with respect to said frame A pivot connection for supporting the second end of the deck so as to pivot in the vertical direction with respect to the frame ;
(F) has, at least one elongate spring is disposed in the longitudinal direction of the deck located between the pivot connection with the first end of the deck between the frame and the deck , the spring than to support the deck relative to the frame together with the pivot connection vertically movably, to absorb the load applied to the deck by the exerciser, and, towards the frame when the exerciser to stepping on the belt A treadmill for body training characterized by resisting the movement of the deck. 35. The frame of claim 34, wherein the frame includes a pair of elongate side rails that are spaced apart from each other by a plurality of transverse members, and the spring is between each side rail and the underside of the deck. A treadmill, wherein the treadmill is disposed at a position. 35. The treadmill according to claim 34, wherein the spring is reversibly deformable under a load applied to the deck by the athlete. 37. A treadmill according to claim 36, wherein the spring provides 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. A treadmill according to claim 37, wherein the rate of reversible deformation of the spring is inversely proportional to the degree of deformation of the spring. The treadmill according to claim 38, wherein the spring is made of an elastomer member. The treadmill according to claim 34, wherein the spring rate of the spring is adjustable. 41. The spring of claim 40, wherein the spring includes a bag configured to receive the compressible fluid, means for supplying the compressible fluid to the bag, and means for removing the compressible fluid from the bag. A featured treadmill. In claim 41, the frame has a recess for receiving a bag, treadmill, characterized in that so as to assist the positioning of the bag against the frame. 35. A treadmill according to claim 34, wherein the spring is at least partially hollow. 44. The treadmill according to claim 43, wherein the spring is composed of an elastic member having a base portion and a convex bulging main body extending outward from the base portion. 45. A treadmill according to claim 44, wherein the bulging body of the spring is formed of an elastomer material. 45. The treadmill according to claim 44, wherein the thickness of the bulging main body is reduced in a direction away from the base portion. 45. A treadmill according to claim 44, further comprising means for mounting a spring at a selected position in the length direction of the side rail. 44. A treadmill according to claim 43, comprising a compressible insertion member configured in a size and shape that can be inserted into the hollow portion of the spring to a selected extent. 49. The treadmill according to claim 48, wherein the spring has a hollow portion along a substantial part of its length, and the length of the insertion member has at least half the length of the hollow portion. 49. A treadmill according to claim 48, wherein the insertion member is tapered along its length. 49. The treadmill according to claim 48, further comprising means for gradually inserting the insertion member into the spring and withdrawing the insertion member from the spring. 35. The pivot connection of claim 34, wherein the pivot connection includes hinge means for frame mounting the second end of the deck so that the second end rotates about an axis extending generally perpendicular to the deck length. A treadmill characterized by the fact that 53. The hinge means according to claim 52, comprising a spindle provided on an orthogonal rotation shaft of the hinge means, and a hinge bracket connected to the spindle and attached to one of the second ends of the deck and the frame. A treadmill characterized by

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