The disclosed technique relates to exercise apparatuses in general, and to limb-exercising apparatuses for retrofitting to swivel chairs on castors, in particular.
Numerous studies have shown that continuous sitting for prolonged periods (i.e., more than three hours at a time) may increase the risk of developing certain diseases (e.g., diabetes, heart disease, liver disease) even for those individuals who are engaged and practice daily physical activity. With an ever increasing number of modern-day workplaces (i.e., desk jobs) than before, individuals are less physically active during certain hours of the day. Such periods of relative physical inactivity affects the body's metabolism such that there is deceased blood circulation, as well as adverse blood sugar and triglyceride levels, which in turn affect the body's mechanism associated with the regulation and storage of body fat. Furthermore, studies have also shown that periods of prolonged sitting may contribute to poor posture, and may cause accumulated mechanical trauma to the joints (e.g., knees, ankles, pelvis, back, neck) as well as to the spine. Various approaches have been proposed that claim to address this sedentariness and thus aim to lower one's risks involved in continuous and prolonged sitting while working.
Exercise apparatuses, in general, for use with office chairs are known in the art. U.S. Patent No.: U.S. Pat. No. 7,648,447 B2 issued to Andre and entitled “Leg exercise device for use with an office chair” is directed to an exercise device that is constructed to be connected to the vertical seat support of the office chair. The device includes a leg exercise mechanism and a rigid connection mechanism. The leg exercise mechanism, which is a pedaling mechanism, includes opposite rotating pedals, drive housing, and a tension control knob. The rigid connection mechanism includes a first lateral arm, a rectangular brace, a flange, an angled second arm, a penannular collar, and a tightening pin. The pedaling mechanism extends laterally from the drive housing. The first lateral arm is movably connected to the rectangular brace. The rectangular brace is used for adjusting the lateral distance of the pedaling mechanism from the office chair. The leg exercise device is secured to the office chair such that the pedaling mechanism is positioned in front of a user of the leg exercise device. The collar is secured to the vertical seat support of the office chair by inserting the vertical seat support through the open portion of the penannular collar and then tightening the tightening pin against the vertical seat support. Using the leg exercise device is accomplished by sitting on the office chair seat and pedaling the pedaling mechanism.
It is an object of the disclosed technique to provide a novel apparatus for enabling physical exercise by a user, who sits on a swivel chair, in an office setting, which overcomes the disadvantages of the prior art.
According to the disclosed technique, there is thus provided a limb-exercising system for coupling (i.e., attaching, retrofitting) to or manufacturing with the swivel chair. The swivel chair typically includes a plurality of chair legs, a plurality of castors, and a plurality of pivotal pins. Each pivotal pin couples a chair leg with a castor, and each pivotal pin extends upwardly across a gap between the castor and the chair leg. The limb-exercising system includes a rigid framework, at least one limb-exercising unit, a force resistor and a cable. The rigid framework includes at least three chair couplers that are each coupled, at least partially circumferentially, with respective one of at least three of the pivotal pins, substantially within the gap, such to allow rotation of the castors, and such that the relative movement between the rigid framework and the swivel chair is minimal. The limb-exercising unit is coupled with the rigid framework. Each limb-exercising unit is operative to provide movement exercise for at least one muscle group of the body of a user. The force resistor is coupled with the rigid framework and with the limb-exercising unit. The force resistor provides resistance to movement of the limb-exercising unit. The cable couples between limb-exercising unit and the force resistor.
According to another aspect of the disclosed technique, there is thus provided a limb-exercising system for coupling (i.e., attaching, retrofitting, etc.) to or manufacturing with the swivel chair by employing at least one chair coupler. The swivel chair includes a plurality of chair legs that define a chair leg base that has an underside. The limb-exercising apparatus includes a rigid framework, at least one limb-exercising unit, a force resistor, and a cable. The rigid framework includes at least one chair coupler that couples the rigid framework with the chair leg base, such that the relative movement between the rigid framework and the swivel chair is minimal. The at least one limb-exercising unit is coupled with the rigid framework. Each limb-exercising unit is operative to provide movement exercise for at least one muscle group of the body of a user. The force resistor is coupled with the rigid framework and with the limb-exercising unit. The force resistor provides resistance to movement of the limb-exercising unit. The cable couples between the limb-exercising unit and the force resistor.
The disclosed technique will be understood and appreciated more fully from the following detailed description taken in conjunction with the drawings in which:
The disclosed technique overcomes the disadvantages of the prior art by providing a limb-exercising apparatus for retrofitting to existing swivel chairs on castors such that the mobility of the swivel chair is not compromised. The limb-exercising apparatus is constructed to be easily mounted to typically standard multi-legged swivel chair on castors, and may be dismounted from the swivel chair, when required. The limb-exercising apparatus provides a user who is seated in a retrofitted swivel chair, with the ability to concurrently perform his or her occupation (e.g., desk job) while exercising, without producing substantial machine noise in the process. The limb-exercising apparatus provides hands-free operation such that it does not constrain the user in carrying out desk jobs that typically entail for example, computer use (e.g., via keyboard, mouse, hand-gestures) the handling of documents, reading, speaking over the phone, “hand-talking”, and the like. When correctly mounted on the swivel chair (and correctly used), the limb-exercising apparatus is constructed and operative to minimize potential occupational safety hazards associated with its use (i.e., in comparison with prior art exercising apparatuses that employ weights), such as for example, the prevention of tipping over of the user, as well as easy disengagement when there is a need for fast evacuation of the premises during emergencies (e.g., fires, earthquakes).
In essence, the limb-exercising apparatus is constructed and operative for coupling to typically standard existing swivel chairs that include a plurality of chair legs defining a chair leg base that has an underside. The limb-exercising apparatus includes a rigid framework, at least one limb-exercising unit, a force resistor, and a cable. The rigid framework includes at least one chair coupler that couples the rigid framework with the chair leg base (i.e., so that the limb-exercising apparatus is disposed underneath the chair leg base), such that the relative movement between the rigid framework and the swivel chair is minimal. The rigid framework is coupled with the limb-exercising unit and with the force resistor, which in turn is coupled with the limb-exercising unit via the cable. The limb-exercising unit is operative to provide movement exercise for at least one muscle group of the body of a user. In accordance with another embodiment, the rigid framework is operative to be coupled with the pivotal pins of the swivel chair. Each pivotal pin extends upwardly across a gap between the castor and the chair leg, such that the pivotal pin, in effect couples a chair leg with a castor. The rigid framework includes at least three chair couplers that are each respectively coupled, at least partially circumferentially, with at least one of at least three pivotal pins, substantially within these gaps. The gaps allow free rotation of the castors and thus multi-directional movement of swivel chair upon the ground that supports it. The chair couplers are constructed and operative to couple the rigid framework with the swivel chair such that the relative movement between the rigid framework and the swivel chair is minimal and such to further allow free rotation of the castors on the ground. The limb-exercising apparatus and swivel chair may further be manufactured as a single unit (e.g., as a mass-produced, factory-made item), such that for example, at least part (e.g., the outer covering) of the limb-exercising apparatus is incorporated into the structure of swivel chair.
The term “force resistor” used herein throughout the detailed description and the claims refers to an apparatus that at least partially resists force applied thereto in at least one component direction that is opposite to the direction of the applied force. Force resistor may be, for example, implemented as a helical torsion spring, a torsion spring, a torsion bar, a double torsion spring, a geared resistance mechanism, an apparatus having multiply distinct cooperating components that provide resistance in response to applied motion to at least one of the distinct cooperating components, and the like. The terms “underside” and “underneath” used herein throughout the detailed description and the claims in the context that relates to swivel chair, refers to any part of the swivel chair that is disposed between the chair leg base (included) and the ground upon which the swivel chair is supported.
Reference is now made to
Internal spring shaft 118 and internal spring tensioning shaft 122 are each coupled to respective opposite extremities 117L and 117R of helical torsion spring 116. In particular, helical torsion spring 116 is coiled, along at least part of its length (including extremity 117L) around internal spring shaft 118 so as to substantially allow for torque to be transmitted therebetween. Helical torsion spring 116 defines a rotation/twisting axis 119 about which helical torsion spring 116 twists (and untwists). Rotation of internal spring shaft 118 produces a corresponding rotation (twisting/untwisting) of helical torsion spring 116 about twisting axis 119, and vice-versa. Flanged spool 120 is concentrically mounted and mechanically coupled (e.g., rigidly) to internal spring shaft 118 such to allow torque to be substantially transmitted therebetween. Rotation of flanged spool 120 about rotation axis 119 produces a corresponding rotation of internal spring shaft 118, and vice-versa. Flanged spool 120 is generally cylindrical in shape, rigidly and coaxially mounted on outer periphery of internal spring shaft 118 via a bearing (e.g., a ball bearing, not shown). Flanged spool 120 is operative to enable winding and unwinding of cable 112 circumferentially thereon. Internal spring shaft 118 and flanged spool 120 may be manufactured as a single unit. Helical torsion spring 116, at extremity 117R, is coiled, along at least part of its length, around internal spring tensioning shaft 122. Rotation of internal spring tensioning shaft 122 about rotation axis 119 produces a corresponding rotation (twisting/untwisting) of helical torsion spring 116. Tension adjuster 124 is coupled with internal spring tensioning shaft 122. Tension adjuster 124, which is rotatable with respect to rotation axis 119, includes a locking mechanism 125 for locking the angular position of extremity 117R with respect to the angular position of extremity 117L of helical torsion spring 116. The relative difference in angular positions between extremities 117R and 117L determine how much helical torsion spring 116 is twisted (i.e., with respect to its untwisted state) and thus the amount of mechanical energy stored therein.
Chair couplers 106A, 106B, 106C are coupled at different (angular) positions with respect to framework 102 via respective chair coupler supports 114A, 114B, 114C (i.e., typically substantially parallel with the longitudinal extend of framework 102). Chair couplers 106A, 106B, 106C are constructed and operative to be each independently fixatedly adjustable (e.g., via screws) along the lengths of respective elongated slots 136A, 136B, 136C such so enable varying outwardly projecting lengths with respect to framework 102. In other words, chair couplers 106A, 106B, and 106C are length-wise independently adjustable. Male snap fasteners 130A, 130B, 130C, and 130D and female snap fasteners 132A and 132B of framework 102 are operative to engage and interlock with corresponding reciprocal (i.e., and complementary) members (i.e., male-female, female-male) snap fasteners located on the underside of top cover 104 (not shown), thereby securing top cover 104 to framework 102, as depicted in
According to the present embodiment of the disclosed technique, the coupling of framework 102 of limb-exercising apparatus 100 to the underside an office swivel chair is accomplished by the engagement of U-shaped notches 138A, 138B, and 138C with respective vertical pivotal pins of the swivel chair, as will be described in detail hereinbelow. Extendable and retractable cart 110 is generally a limb-exercising unit (i.e., typically the legs of a user), that could be interchanged with other types of limb-exercising units (not shown). Helical torsion spring 116 is a force resistor that provides resistance to exercise movements produced by the user, the specifics of which will be described in detail hereinbelow.
Reference is now further made to
Reference is now further made to
Extendable and retractable cart 110 includes a cart body 148, a footrest platform portion 150, a cart ramp retainer engaging portion 152, a cable coupling portion 154, a front right cart wheel 156FR, a front left cart wheel 156FL, a rear right cart wheel 158RR, a rear left cart wheel 158RL, a front wheels axle 160, a rear wheels axle 162, a plurality of front axle brackets 164A, 164B, and 164C, and a plurality of rear axle brackets 166A, and 166B. Front axle brackets 164A, 164B, and 164C, as well as rear axle brackets 166A, and 166B are formed as an integrated part of cart body 148. Alternatively, the brackets are distinct from and separate from cart body 148 and are assembled thereto during manufacture of limb-exercising apparatus 100. Front right cart wheel 156FR and front left cart wheel 156FL are each coupled with the opposite extremities of front wheels axle 160. Similarly, rear right cart wheel 158RR and front left cart wheel 158 are each coupled with the opposite extremities of rear wheels axle 162. Front wheels axle 160 is coupled with front axle brackets 164A, 164B, and 164C, such to allow free rotation thereof about the longitudinal axis of symmetry of front wheels axle 160. Similarly, rear wheels axle 162 is coupled with rear axle brackets 166A and 166B, such to allow free rotation thereof about the longitudinal axis of symmetry of rear wheels axle 162. Cable coupling portion 154 allows coupling cable 112 thereto (
Limb-exercising apparatus 100 is constructed and operative to be coupled with an underside of a chair leg base that includes a plurality of chair legs of a swivel chair. For further detail, reference is now further made to
A general connectivity between parts of a typical multi-legged (usually five-legged) swivel chair (e.g., swivel chair 10) is such that elongated vertical seat support 18 rotatably couples between seat 12 and chair leg base 20, providing full (i.e., 360°) rotational movement of seat 12 with respect to chair leg base 20. Seat 12 supports (most of) the weight of a user (sitter—not shown) seated thereon, backrest 14 provides support to the back (not shown) of the user, and respective right and left arm supports 16R and 16L, each coupled with a respective side of seat 12, provide support for the arms (not shown) of the user. Each one of castors 26A, 26B, 26C, 26D, and 26E is rotatably coupled with underside 22 of a respective chair leg 24A, 24B, 24C, 24D, and 24E via a respective pivotal pin 28A, 28B, 28C, 28D, and 28E. Each pivotal pin 28A, 28B, 28C, 28D, and 28E includes respective flanges 30A, 30B, 30C, 30D, and 30E that circumferentially project from the respective pivotal pin (i.e., about each pivotal pin longitudinal rotation axis), such that the outer diameter of each flange is approximately 4 millimeters larger that the diameter of its respective pivotal pin. Each one of flanges 30A, 30B, 30C, 30D, and 30E has a width of approximately 2 millimeters (i.e., in other words, when a pivotal pin is in the vertical direction, its respective flange is approximately 2 millimeters in height). Each pivotal pin 28A, 28B, 28C, 28D, and 28E extends upwardly across gaps (i.e., typically on the order of 2 millimeters in the vertical direction) that exist between underside 22 of the chair legs and each castor. Each such gap allows castors 26A, 26B, 26C, 26D, and 26E to rotate freely about their respective longitudinal pivotal pin rotation axes 32A, 32B, 32C, 32D, and 32E (in the vertical direction), as shown in
Limb-exercising apparatus 100 is constructed and operative to be coupled with underside 22 of swivel chair leg base 20. The coupling of limb-exercising apparatus 100 with swivel chair 10 will now be described in greater detail. In accordance with the present embodiment of the disclosed technique, limb-exercising apparatus 100 is coupled with swivel chair 10 within the gaps that exist between underside 22 and castors 26A, 26B, 26C, such that at least three chair couplers 104A, 104B and 104C are each respectively coupled with at least one pivotal pin 28A, 28B, and 28C, as shown in
The rigid coupling of framework 102 with swivel chair 10, involves fixatedly adjusting the outward projection lengths of chair couplers 106A, 106B, and 106C (i.e., via respective elongated slots 136A, 136B, and 136C) so that they engage with respective pivotal pins 28A, 28B, and 28C. Each chair coupler 106A, 106B, and 106C is typically constructed from a rigid material such as metal (e.g., steel), reinforced plastic, or other suitable material, whose thickness is such to allow the sufficient vertical length of pivotal pins 28A, 28B, and 28C to remain securely lodged within respective castor vertical cylindrical grooves 27A (not shown), 27B (not shown), and 27C. This coupling provides a rigid connection of rigid framework 102 with swivel chair 10, such that the relative movement therebetween is minimal. Chair couplers 106A, 106B, and 106C are extendable-retractable with respect to respective elongated guides 107A, 107B, and 107C such to facilitate coupling of rigid framework 102 with different swivel chairs of varying chair leg lengths. Alternatively, chair couplers 106A, 106B and 106C are angularly variable (not shown) with respect to framework 102 so as to allow coupling with swivel chairs having differently angular displaced leg configurations (i.e., multi-legged swivel chairs whose chair legs are not displaced in equiangular relationship therebetween).
In general, operation and use of limb-exercising apparatus 100 (by a user thereof) enables the user to exercise muscle groups of the legs (e.g., the quadriceps, etc.) while in a seated position in swivel chair 10. Limb-exercising apparatus 100 enables the user to exercise either left or right legs separately, or both legs simultaneously. Exercising and training typically involves working the leg muscles by repeatedly moving against resistance the extendable and retractable cart across the ground. Essentially, there are two distinct and extreme positions that are realized with limb-exercising apparatus 100 that will be termed as: the fully retracted position and the fully extended position. Commonsensically, there are a multitude of other intermediate positions that can be attained within this range between the fully retracted position and the fully extended position (not shown). The operation and use of limb-exercising apparatus 100 will now be described in greater detail in conjunction with the following drawings. Reference is now further made to
In general, hinged ascending and descending cart camp 108 is operative to assume a fully ascended position and a fully descended position. In the fully ascended position limb-exercising apparatus 100 keeps away from contact with the ground, and in the fully descended position, both hinged ascending and descending cart ramp 108 and extendable retractable cart 110 make contact with a substantially flat ground upon which the swivel chair is supported. Prior to operating limb-exercising apparatus 100, a user assumes a seated position (not shown) in swivel chair 10. In this initial position of user, prior to the commencement of physical exercise on limb-exercising apparatus 100, extendable and retractable cart 110 is at the fully retracted position, as shown in
To perform exercises on limb-exercising apparatus 100, the user initially places his or her feet on footrest platform portion 150 of extendable and retractable cart 110. Limb-exercising apparatus 100 enables the user to perform resistance exercises against the resistance to movement or twisting provided by the force resistor (e.g., helical torsion spring 116), whether in an action that progressively pushes against resistance or conversely, in an action that progressively releases against resistance.
Pushing against resistance exercises involves the user impelling extendable and retractable cart 110 forward and away from swivel chair 10, toward the fully extended position of limb-exercising apparatus 100 or any other intermediate position thereof, against the resistance of helical torsion spring 116, in a manner that induces muscular contraction of the user's leg muscles.
Releasing against resistance exercises involves the user gradually resisting the pulling force exerted on extendable and retractable cart 110 by helical torsion spring 116 via cable 112 from any extended position (i.e., full or intermediate) toward the fully retracted position of limb-exercising apparatus 100 or any other intermediate position thereof. This reverse-resistance action, in the opposite direction, also provides exercise to the user, by inducing muscular contraction of the user's leg muscles.
Tension adjuster 124 includes a plurality of settings (not shown) that correspondingly determine the amount of resistance exerted by helical torsion spring 116. Specifically, the amount of resistance provided by helical torsion spring 116, and thus the amount of physical exertion or load required for progressively extending or retracting extendable and retractable cart 110 can be controlled by rotating tension adjuster 124 (
In accordance with another embodiment of the disclosed technique, the limb-exercising apparatus is constructed and operative to be coupled with the swivel chair leg base, such that limb-exercising apparatus is located at the underside of the swivel chair leg base, without necessitating coupling to the pivotal pins of the swivel chair. In such an implementation, the limb-exercising apparatus includes at least one chair coupler that is operative to couple the rigid framework of the limb-exercising apparatus with the underside of the swivel chair leg base, such that the relative movement between the rigid framework and the swivel chair is minimal. Alternatively, the top cover, to which the rigid framework is coupled with, is coupled to the underside of the swivel chair leg base. Such couplings (i.e., between rigid framework and underside of swivel chair) may be realized by various techniques such as, for example, by fastening (e.g., via screws, snap fasteners, Velcro®, etc.), adhering (i.e., by an adhesive), strapping, clasping, molding together in the manufacturing phase the framework or top covering thereof with the underside of swivel chair base, and the like.
To further elucidate the particulars of this embodiment, reference is now made to
The coupling of limb-exercising apparatus 200 with swivel chair 10 is not limited only to the use of a particular type and quantity of chair couplers (e.g., three), for it may be implemented by only one chair coupler, such as in the case of the use of an adhesive material (i.e., that bonds top cover 104 with underside 22), a thermo-adhesive material (not shown), a single mechanical coupler mechanism (e.g., a arbitrarily-shaped mechanical structure, a structure that at least partially surrounds or partially within circular through-hole 134, a three-bar linkage, a four-bar linkage, etc.), an apparatus having multiply distinct components, or any other suitable mechanical structure or structures that may be used and adapted for achieving that purpose. Further alternatively, limb-exercising apparatus 200 is still located at the underside of the swivel chair leg base 20 but is coupled with any part (i.e., including upper and/or side portions) of swivel chair leg base 20 by employing for example, wires (not shown), strings (not shown), mechanical fittings (not shown), an array of fasteners (not shown), and the like. Further alternatively, at least part of limb-exercising apparatus 100 (e.g., top cover 104) is formed with at least part of chair leg base 20 in their mutual manufacturing process, such that part of limb-exercising apparatus 100 is incorporated into part of swivel chair 10 (e.g., underside 22 of chair leg base 20).
It will be appreciated by persons skilled in the art that the disclosed technique is not limited to what has been particularly shown and described hereinabove. Rather the scope of the disclosed technique is defined only by the claims, which follow.
Number | Date | Country | |
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60928170 | May 2007 | US |
Number | Date | Country | |
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Parent | 12598542 | Mar 2010 | US |
Child | 13941690 | US |