APPARATUS FOR PHYSICAL EXERCISES

Abstract

An apparatus for performing abdominal exercises, the apparatus comprising a frame (10) for providing a stable base for operation of the apparatus, a seat (14) for a user to rest onto, a resistance adjustment means (20) for adjusting level of resistance for operation of the apparatus and a joint mechanism (22) for bearing loads and providing rotational movement, wherein the resistance adjustment means (20) is operable to resist movement of the joint mechanism (22) located at centre point of the frame (10), characterized in that an arm (16) connected to the joint mechanism (22) located at centre point of the frame (10) is rotatable at centre point of the frame (10) by means of the joint mechanism (22) and the seat (14) is linearly connected to the arm (16) and is linearly traversable about the arm (16) and the seat (14) is further rotatably connected to the arm (16).

Claims

1. An apparatus for performing abdominal exercises, the apparatus comprising: a frame for providing a stable base for operation of the apparatus; a seat for a user to rest onto; a resistance adjustment means for adjusting level of resistance for operation of the apparatus; and a joint mechanism for bearing loads and providing rotational movement; wherein the resistance adjustment means is operable to resist movement of the joint mechanism located at centre point of the frame, wherein: i) an arm connected to the joint mechanism located at centre point of the frame is rotatable at centre point of the frame by means of the joint mechanism; and ii) the seat is linearly connected to the arm and is linearly traversable about the arm and the seat is further rotatably connected to the arm.

2. The apparatus as claimed in claim 1, wherein the arm is connected to the joint mechanism at terminal end of the arm.

3. The apparatus as claimed in claim 1, wherein the resistance adjustment means produces resistance in the form of mechanical friction between resistance adjustment means and joint mechanism.

4. The apparatus as claimed in claim 1, wherein the resistance adjustment means comprises of: i) a lever; ii) a brake cable; and iii) a brake pad, wherein squeezing the lever pulls the brake cable taut which tightens the brake pad around the joint mechanism while releasing the lever slackens the brake cable which loosens the brake pad around the joint mechanism.

5. The apparatus as claimed in claim 1, wherein the seat is connected to the arm via a roller bracket and is linearly traversable about the arm by means of rollers connected to the roller bracket, the rollers rolling in grooves formed on the arm.

6. The apparatus as claimed in claim 6, wherein the seat is rotatable at the arm about its own vertical axis by means of a seat joint mechanism attached to the roller bracket.

7. The apparatus as claimed in claim 1, wherein the seat is made of non-slip material.

8. The apparatus as claimed in claim 7, wherein non-slip material is selected from a group consisting of rubber, silicone and polyurethane or combination thereof.

9. The apparatus as claimed in claim 1, wherein the apparatus further comprises of handles for user to hold onto during operation of the apparatus.

10. The apparatus as claimed in claim 9, wherein the handles are laterally extendible and retractable.

11. The apparatus as claimed in claim 3, wherein the resistance adjustment means is connected to the handle.

12. The apparatus as claimed in claim 9, wherein the resistance adjustment means is connected to the handle.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0011] The drawings constitute a part of this specification and include an exemplary or preferred embodiment of the invention, which may be embodied in various forms. It should be understood, however, the disclosed preferred embodiment is merely exemplary of the invention. Therefore, the figures disclosed herein is not to be interpreted as limiting, but merely as the basis for the claims and for teaching one skilled in the art of the invention.

[0012] FIG. 1 shows an abdominal exercise machine being a preferred embodiment of the present invention.

[0013] FIG. 2a shows an exploded view of the abdominal exercise machine of FIG. 1.

[0014] FIG. 2b shows a magnified exploded view of a seat shown in FIG. 2a.

[0015] FIG. 2c shows a magnified exploded view of an arm and a joint mechanism shown in FIG. 2a.

[0016] FIG. 2d shows a magnified exploded view of a resistance adjustment means shown in FIG. 2a.

[0017] FIG. 2e shows a magnified exploded view of a frame and a pair of handles shown in FIG. 2a.

[0018] FIG. 2f shows a cross sectional view of a seat connected to a seat joint mechanism.

[0019] FIG. 2g shows a cross sectional view of a joint mechanism connected to a central shaft.

[0020] FIG. 3 shows the abdominal exercise machine of FIG. 1 with seat and arm removed.

[0021] FIGS. 4a and 4b show top and bottom isometric views of a seat and arm.

[0022] FIG. 5 shows a person operating the abdominal exercise machine of FIG. 1.

DETAILED DESCRIPTION OF THE DRAWINGS

[0023] Detailed description of preferred embodiment of the present invention is disclosed herein. It should be understood, however, that the embodiment is merely exemplary of the present invention, which may be embodied in various forms. Therefore, the details disclosed herein are not to be interpreted as limiting, but merely as the basis for the claim and for teaching one skilled in the art of the invention. The numerical data or ranges used in the specification are not to be construed as limiting.

[0024] FIG. 1 a shows a preferred embodiment of the present invention wherein an apparatus being an abdominal exercise machine comprises of a frame (10), handles (12), seat (14), arm (16), circular rail (18) and a resistance adjustment means (20). The frame (10) houses all components and provides a stable base for operation of the apparatus. The arm (16) is connected to centre point of the frame (10) via a joint mechanism (22). The arm (16) rotates about the centre point of the frame (10) with outer end of the arm (16) having a roller (which is shown is subsequent figures) which travels on the circular rail (18). The handles (12) allow a user to hold onto them for support while operating the apparatus and are extendable sideways to accommodate size of user, wherein a larger bodied user would push out handles (12) for a more convenient grip while a smaller bodied user would withdraw handles (12) to achieve the same. A resistance adjustment means (20) is provided at one of the handles (12) for user to adjust desired amount of resistance by operating the resistance adjustment means (20). It is appreciated that the resistance adjustment means (20) is operable without being attached to the handle (12). Non-slip foot covers (26) made of non-slip material such as rubber, silicone and polyurethane or combination thereof are provided to increase friction between feet (24) of apparatus and ground surface to prevent the apparatus from sliding or moving around during operation of the apparatus. It is imagined that any variation in number of feet (24) may be possible or that frame (10) of the apparatus engages ground surface by means of a single, solid base without any feet without departing from scope of invention.

[0025] FIG. 2a shows an exploded view of the preferred embodiment of the present invention, while FIG. 2b shows a magnified exploded view of a seat, FIG. 2c shows a magnified exploded view of an arm, FIG. 2d shows a magnified exploded view of a resistance adjustment means while FIG. 2e shows a magnified exploded view of a frame and handles.

[0026] With further reference to FIGS. 2b and 2c, seat assembly comprising of a seat (14), a shaft (14b) connected to seat joint mechanism (14c) and a roller bracket (14a) with rollers (14d) connected to the shaft (14b) and seat joint mechanism (14c). Bolts (28) secure the shaft (14b) to the seat (14). The seat joint mechanism (14c) allows the seat (14) to rotate at the shaft (14b) while rollers (14d) allow the seat (14) roll freely in a linear direction. Various components within the seat joint mechanism (14c) will be explained further in FIG. 2f.

[0027] The seat (14) is linearly connected to an arm (16) on which it is linearly traversable. Further, the seat (14) is also rotatable about its own vertical axis at any point along the arm (16) by means of the seat joint mechanism (14c). The arm (16) is also connected to a joint mechanism (22) which in turn is connected to a central shaft (30) located at centre point of the frame (10) to allow the arm (16) to rotate about centre point of the frame (10). A roller (16a) is located at the bottom of the arm (16) and the roller travels on the circular rail (18). The roller (16a) functions to help bear load of a user together with the joint mechanism (22) during operation of the exercise apparatus. This is to prevent the arm (16) from deflecting under load.

[0028] With further reference to FIG. 2d, a resistance adjustment means (20) comprises of a lever (20a), brake cable (20b), and a brake pad (20c). The lever (20a) and brake pad (20c) are connected via the brake cable (20b) and the brake pad (20c) encircles the joint mechanism while the lever (20a) can be held freely with one hand or attached to a handle. In the preferred embodiment, the resistance adjustment means (20) is attached to the handle. The lever (20a) is operable to apply braking force against joint mechanism by the brake pad (20c) or to release joint mechanism based on force exerted on the lever (20a).

[0029] With further reference to FIG. 2e, handles (12) are configured to fit into slots (32) formed on the frame (10) so that the handles (12) can be laterally extended and retracted within the slots (32). In this embodiment, the handles (12) are detachable to allow for ease of storage to reduce the apparatus to a compact form. Alternatively, the handles (12) are foldable and locked into position by a latch, screw or bolt.

[0030] While the frame (10) in the preferred embodiment is rectangular in shape, it is envisioned that a minimal, skeletal frame (not illustrated) can be used to provide the same amount of stability and rigidity while being lighter in weight.

[0031] FIG. 2f shows a cross section view of the seat (14) connected to the seat joint mechanism (14c). Bolts (28) fasten the seat (14) to a frame from which a shaft (14b) protrudes. The shaft (14b) is positioned below the seat (14) and protrudes downwards wherein the shaft (14b) meets the seat joint mechanism (14c). Contained within the seat joint mechanism (14c) is a ball bearing (34) is secured to the shaft (14b) by means of a lock ring (14g) clamped around a groove (14h) formed on the shaft (14b). The lock ring (14g) holds the ball bearing (34) in place to prevent the ball bearing (34) from moving vertically along the shaft (14b) during operation of the apparatus. The ball bearing (34) is further secured to its position by a cover (14e) covering the seat joint mechanism (14c). A washer (14f) fills the space between the cover (14e) and ball bearing (34).

[0032] FIG. 2g shows a cross section view of the central shaft (30) protruding upwards from the central shaft base plate (30a). The joint mechanism (22) is rotatably secured to the central shaft (30) by means of a nut (22b) which also secures a ball bearing (34) contained within the joint mechanism (22). It can be seen that the central shaft (30) tapers to a wider diameter below the ball bearing (34) and the taper prevents the ball bearing (34) from sliding down the central shaft (30). At bottom end of the central shaft (30), a plurality of washers (22c) are placed to support the joint mechanism (22) and prevent the joint mechanism (22) from tilting in any direction as it rotates. A cover (22a) seals the joint mechanism (22) to prevent infiltration of foreign matter into the joint mechanism (22).

[0033] Ball bearings (34) are used as a preferred means to support loads and facilitate rotation in the joint mechanism (22) and seat joint mechanism (14c), however, other types of rotational joints known to a person skilled in the art such as swivel joints or ball joints are envisioned to be also suited for the application of supporting loads and facilitating rotation.

[0034] FIG. 3 shows the apparatus with the seat and arm removed to expose the joint mechanism (22) and resistance adjustment means (20). The joint mechanism (22) rotates freely about central shaft (hidden from view) and applying braking force against the joint mechanism (22) will retard movement of the joint mechanism (22), which in turn retards movement of the arm (not illustrated in this figure). When no force is exerted to squeeze the lever (20a), the brake cable (20b) is slack and there is no braking force acting on the joint mechanism (22) by the brake pad (20c). Squeezing the lever (20a) will cause the brake cable (20b) to become taut and in turn pull together both ends of the brake pad (20c). This will cause the brake pad (20c) to tighten around the joint mechanism (22) and apply braking force against the joint mechanism (22) and therefore creates mechanical friction and therefore retards movement of the joint mechanism (22). This in turn creates resistance for a user using the apparatus for exercise in order to increase difficulty of the exercise. As more force is applied by the user to squeeze lever (20a), more braking force is consequently applied against joint mechanism (22) which increases resistance and therefore the exercise becomes more challenging. The user is free to apply the necessary force to achieve desired level of difficulty to perform the exercise. This means of providing resistance is preferred as the user can instantaneously increase or decrease resistance of exercise performed on the apparatus by squeezing or releasing the lever (20a) as compared to other types of mechanism such as a dial-adjustment mechanism which requires repeated twists of a dial to increase or decrease resistance.

[0035] Other means of providing resistance include using brakes with a dial-adjusted mechanism (not illustrated) wherein the brake is moved closer to or further from the joint mechanism by turning the dial. Turning the dial to cause the brake to tighten around the joint mechanism will increase resistance of activity while turning the dial to cause the brake to loosen around the joint mechanism will decrease resistance of the activity.

[0036] Still another means of providing resistance include using a dial adjusted mechanism to move a magnet closer or further to the joint mechanism (not illustrated). Moving the magnet closer to the joint mechanism creates a resistive magnetic force between the magnet and joint mechanism which resists movement of the joint mechanism without physically contacting the joint mechanism. Moving the magnet further from the joint mechanism lessens the resistive magnetic force. It is envisioned that still other means of providing resistance can be used without departing from the scope of the invention.

[0037] FIG. 4a and FIG. 4b show top isometric view and bottom isometric view of the seat (14) which is connected to the arm (16) via a roller bracket (14a). The seat (14) is linearly traversable on the arm (16) by means of the rollers (14d) set into grooves (16b) formed at sides of the arm (16). As the rollers (14d) protrude inwardly into the grooves (16b) at sides of the arm (16), the seat (14) does not fall of during vigorous operation of the apparatus.

[0038] The seat (14) is layered at the top with a non-slip material such as rubber, silicone or polyurethane or a combination thereof to prevent user from sliding off the seat during operation of the apparatus. It is envisioned that the seat (14) can be padded with cushioning material such as foam or rubber for comfort and also equipped with restraining means such as safety belts to further prevent user from sliding off the seat during operation of the apparatus.

[0039] FIG. 5 shows a user seated on the apparatus. Seat (14) has two different freedom of motion which is rotational movement (A) about its own vertical axis and linear movement (B) towards and away from centre point of the frame (10), limited by length of arm (16). The arm (16) is rotatable about the centre point of the frame (10) (C). Combining these freedoms of movement (A, B, C), the user is able to trace any elliptical motions (D) bound by these freedoms of movement using their hip and core muscles for exercise.

[0040] Commercially available exercise equipment for abdominal exercises typically centre on only one degree of motion which is either rotation around a vertical axis, i.e. twisting motion or rotation around a horizontal axis, i.e. abdominal crunch motion. Performing exercises using these motions are not effective as only a small area of the abdomen is exercised and these motions place excessive strain on a user's back which could lead to injury. By combining different freedoms of movement, the apparatus allows a user to perform an elliptical motion (D) for exercising which allows for more muscle groups to be exercised instead of just abdominal muscle group and as twisting or crunching motions are eliminated by performing elliptical motion (D), risk of spinal injury is likewise mitigated.

[0041] To perform an exercise using the apparatus, the user sits on the seat (14) provided and holds onto the handles (12) for stability. Feet of the user are extended outwards and pressed against surface of the ground. The user then traces elliptical motions using hip and core muscles while seated to exercise these muscle groups. By squeezing or releasing the resistance adjustment means (20), the user can increase or decrease resistance of the apparatus and therefore increase or decrease difficulty of the exercise.

[0042] Dimensions of a preferred embodiment of the apparatus is given as below:

[0043] Height of handle: 350 mm

[0044] Width of frame from left to right: 900 mm

[0045] Depth of frame from front to back: 830 mm

[0046] Arm length: 450 mm

[0047] Radius of circular rail: 250 mm

[0048] Height of feet: 50 mm