The invention relates generally to a barbell assembly, and more particularly, to a barbell assembly having impact absorbing weights mounted on a bar and a swivel adjacent at least one end of the bar. A barbell assembly constructed in accordance with the present invention can be used on any exercise or competition surface in any location without damaging the surface in the event the barbell assembly is dropped, while reducing noise and providing increased safety to the user. In addition, a barbell assembly constructed in accordance with the present invention can be used to perform weight training exercises that cannot be performed with a conventional barbell and conventional weights.
Barbell assemblies are well known for performing strength and conditioning exercises, as well as for participating in weight-lifting, power-lifting and strong man competitions. Traditional barbell assemblies consist of an elongate bar and one or more free weights adapted to be mounted adjacent each of the opposite ends of the bar and retained on the bar by a retaining device, such as a removable collar. The bar is typically made of high-strength metal, for example steel, and the free weights are made of a heavy, dense material, such as metal (e.g. steel or pig iron). In some instances, the free weights are encased, covered or coated with a softer material, such as rubber or plastic, to reduce the amount of noise and damage that occurs when the barbell assembly or one of the free weights is dropped onto the exercise or competition surface. Depending on the type of surface, it is also possible that the bar and/or the free weights can be damaged from the impact with the exercise or competition surface.
Many different exercise or competition surfaces can be used with a barbell assembly. Typically, the surface is a substantially firm, rigid floor, for example wood, concrete or asphalt. In many instances, the floor is covered by a mat made of a softer, more energy-absorbing material, such as padded foam or rubber. The mat absorbs some of the impact caused by dropping the barbell assembly or the free weights onto the surface and reduces the noise that results from the weights striking the surface. However, the mat only protects the area of the surface covered by the mat. Accordingly, the surface and the barbell assembly is not protected from damage in the event that the barbell assembly or one of the free weights is dropped on a portion of the surface that is not covered by the mat. Furthermore, the mat does not protect the user from being struck by the heavy free weights, and therefore, does not increase the safety of the user.
United States Patent Application Publication No. US 2011/0009247 A1 published on Jan. 13, 2011, to Richard Zdzislaw Januszek discloses an exercise device weight for mounting to a lifting bar, such as a barbell or dumbbell. The exercise device weight has an inner weight section formed from cast iron and an outer skin formed from polyurethane or rubber material molded about the inner weight section. A plurality of relatively resilient raised surface features project outwardly from the outer skin to define a relief pattern on the circumferential outer surface of the outer skin. The resilient raised projections improve the impact absorption properties of the outer skin, and in particular, act to absorb impact energy and increase deceleration time during impact, thereby providing a softer impact and reducing damage to the exercise device and to other equipment.
U.S. Pat. No. 3,572,702 issued Mar. 30, 1971, to Harry M. Dorn discloses a hollow barbell weight made of an inexpensive, easily molded synthetic material, such as plastic, and provided with a fill opening. The hollow weight is filled with relatively inexpensive and heavy fill material, such as sand, cement, gravel or the like, and the fill opening is closed with a plug. Oftentimes, the plug is dislodged during use and the fill opening is compromised. As a result, the fill material leaks from the opening making the barbell or dumbbell unusable. To protect the weight, and in particular to prevent the plug from coming out, a band of rubber, foamed plastic or other stretchable material is provided that can be expanded to cover the outer circumference of the weight and then permitted to contract so as to firmly engage around the outer periphery of the weight. The band of rubber or like material protects the weight from impact failure in the event the weight is dropped, and physically holds the plug in place over the fill opening.
The aforementioned exercise weights for barbells and dumbbells are intended to protect the weight from impact damage caused, for example, by dropping the weight onto an exercise or competition surface. However, the resilient raised projections of the Januszek exercise device weight and the band of the weight taught by the Dorn patent do not adequately protect the exercise or competition surface from damage in the event that the barbell or dumbbell is dropped. Accordingly, what is needed is an impact absorbing weight for a barbell assembly that adequately protects any exercise or competition surface in any location in the event the barbell assembly or the weight is dropped, while reducing noise and providing increased safety to the user.
Existing barbell assemblies are useful for performing weight lifting exercises. However, a barbell assembly having conventional weights made of a metal or plastic material, whether or not coated or covered with a circumferential band of rubber, foamed plastic or other somewhat elastic material, is not suited for performing weight pushing and/or weight pulling exercises. In particular, as the amount of weight on the barbell is increased, conventional weights tend to gouge, scratch, dig into, or otherwise damage the surface on which the barbell assembly is pushed or pulled. As a result, athletes and body builders must locate and utilize heavily weighted exercise equipment, such as football sleds, to effectively perform weight pushing and weight pulling exercises. Accordingly, what is needed is a barbell assembly having weights suitable for performing weight pushing and weight pulling exercises that will not damage the surface on which the exercise is performed.
The invention is a barbell assembly having impact absorbing weights that can be used on any exercise or competition surface in any location without damaging the surface in the event the barbell assembly is dropped, while reducing noise and providing increased safety to the user. In an exemplary embodiment, a barbell assembly according to the invention includes an elongate bar having opposed ends and a weight subassembly mounted on the bar adjacent each of the opposed ends. Each weight subassembly includes a weight and an inflatable component adapted to be affixed to the weight and inflated. In a particularly advantageous embodiment, the weight is a vehicle wheel and the inflatable component is a vehicle tire that is affixed to the vehicle wheel and inflated.
In other exemplary embodiments, the weight of the weight subassembly has at least one through hole and the barbell assembly further includes a hub having a flange that defines at least one through hole corresponding to the through hole of the weight for attaching the weight and the inflatable component to the hub with at least one fastener. Preferably, the weight has a plurality of through holes that define a predetermined pattern and the flange has a plurality of through holes corresponding to the predetermined pattern. The hub is an elongate annular cylinder and has at least one through hole for receiving a fastener to secure the hub to the bar. Preferably, the hub has a plurality of internally-threaded through holes for receiving a corresponding plurality of externally-threaded fasteners to secure the hub to the bar. In another particularly advantageous embodiment, the barbell assembly further includes a cylindrical inner sleeve made of a deformable material and configured to be disposed between an inner surface of the hub and an outer surface of the bar. The inner sleeve deforms from a circular cross-section to a non-circular cross-section when the at least one fastener secures the hub to the bar by deforming the inner sleeve against the outer surface of the bar.
In other exemplary embodiments, a barbell assembly according to the invention includes an elongate, essentially rigid bar having opposed ends and a weight subassembly mounted on the bar adjacent each of the opposed ends. Each weight subassembly includes a weight having at least one through hole. The barbell assembly further includes a hub defining a flange having at least one through hole corresponding to the through hole of the weight, and the weight is attached to the flange of the hub by at least one fastener. In a particularly advantageous embodiment, the weight has a plurality of through holes that define a predetermined pattern and the flange has a plurality of through holes that define a plurality of predetermined patterns corresponding to predetermined patterns of through holes of a plurality of different weights.
In other exemplary embodiments, a barbell assembly according to the invention includes an elongate, generally cylindrical, essentially rigid bar having opposed ends and a weight subassembly mounted on the bar adjacent each of the opposed ends. Each weight subassembly includes a wheel having at least one through hole and an inflatable component. The barbell assembly further includes an elongate, annular hub defining a flange having at least one through hole corresponding to the at least one through hole of the wheel for securing the weight subassembly to the hub with a fastener. The barbell assembly further includes a cylindrical inner sleeve made of a deformable material and configured to be disposed between an inner surface of the hub and an outer surface of the bar. The hub has at least one through hole for receiving a fastener to secure the hub and the weight subassembly to the bar by deforming and compressing the inner sleeve against the outer surface of the bar. In a particularly advantageous embodiment, the wheel has a plurality of through holes that define a predetermined pattern and the flange has a plurality of through holes that define a plurality of predetermined patterns corresponding to predetermined patterns of through holes of a plurality of different wheels.
In other exemplary embodiments, a barbell assembly according to the invention further includes a rotatable swivel assembly attached to at least one end of the bar that includes a hook adapted to rotate relative to the bar. The hook defines an opening for receiving a tether to secure at least a portion of the barbell assembly to an immovable fixture. The barbell assembly, with or without the swivel assembly, allows an individual to perform a weight pushing exercise using the barbell assembly without causing damage to an exercise surface. The barbell assembly with the swivel assembly allows an individual to perform a weight pulling exercise using the barbell assembly and a tether attached between the individual and the hook of the rotatable swivel assembly at each end of the bar without causing damage to an exercise surface.
The invention, as well as the features, objects and advantages thereof set forth herein, will be better understood and appreciated when considered in light of the detailed description of exemplary embodiments thereof provided hereinafter and the accompanying drawing figures, wherein like reference characters indicate the same or similar parts, elements, components, assemblies or subassemblies.
The invention will be described more fully hereinafter with reference to the accompanying drawings in which one or more exemplary embodiments are shown. However, it is to be understood that the invention may be embodied in many different forms and should not be construed as limited to the exemplary embodiments set forth herein. Exemplary embodiments of the invention are provided herein so that this disclosure will fully and completely convey the broad scope of the invention and to enable one of ordinary skill in the art to make, use and practice the invention without undue experimentation. As previously mentioned, like reference characters in the detailed description and the accompanying drawing figures refer to the same or similar parts, elements, components or assemblies of the invention.
An exemplary embodiment of a barbell assembly constructed according to the invention is shown in
As shown herein, the elongate bar 30 of the barbell assembly 20 has opposed ends 32, 34 and is generally cylindrical in cross-sectional shape. However, the bar 30 may have any desired cross-sectional shape, particularly towards the center of the bar, that is suitable for being grasped by the hands of a user. For example, the cross-sectional shape of the bar 30 may be square, rectangular, or multi-sided (e.g. hexagonal, octagonal, etc.). Preferably, the bar 30 is symmetrical in cross-section for a purpose to be described hereinafter. Regardless, bar 30 is made of a high-strength, essentially rigid material, such as metal, capable of withstanding the bending loads imparted by the weight subassemblies 40 and/or the optional free weights 25 when the barbell assembly 20 is lifted from the exercise or competition surface without yielding. In an advantageous embodiment, the bar 30 is made of carbon steel and, if desired, may be chrome plated for enhanced smoothness and aesthetic purposes. In addition, the medial portion of the bar 30 between the weight subassemblies 40 may be provided with an etched or otherwise uneven surface, for example knurled, to provide an enhanced gripping surface for the user. Regardless, the material, hardening, plating, coating, surface treatment, etc. of the bar 30 is not essential to the invention as long as the bar has mechanical properties suitable for the use and purpose of the barbell assembly. As shown, bar 30 is provided with an optional hook 36 that defines an opening 35 on at least one of the opposed ends 32, 34 of the bar for a purpose to be described hereinafter.
A typical weight subassembly 40 for use with a barbell assembly 20 according to the invention is shown in
As shown and described herein, each weight subassembly 40 comprises a generally cylindrical, annular weight 42 in the form of a wheel having an outer periphery, and an inflatable component 44 mounted on the outer periphery of the wheel. A hub 50 is provided for being attached to the wheel 42 and for subsequently attaching the weight subassembly 40 to the bar 30 of the barbell assembly 20. An optional inner sleeve 60 configured for being disposed between the hub 50 and the bar 30 may also be provided for a purpose to be described hereinafter. The wheel 42 defines a central axial opening 43 configured, and in particular sized and shaped, for receiving an end 32, 34 of the bar 30. The wheel 42 further defines a plurality of through holes 46 (
The hub 50 comprises an elongate, generally cylindrical, annular sleeve 52 and a cylindrical, annular flange 54 that is disposed about and depends radially outward from the sleeve. The sleeve 52 and the flange 54 may be integrally formed from a suitable high-strength, substantially rigid material, such as metal, plastic or composite. Alternatively, the sleeve 52 and the flange 54 may be formed separately and the flange affixed to the sleeve in any suitable manner, for example by press fit, welding, brazing, soldering, fusing, etc. For purposes of material cost and ease of manufacture, the sleeve 52 and the flange 54 are preferably separately formed of machined metal and the surface at the inner periphery of the flange is welded to the surface at the outer periphery of the sleeve. The weld between the flange 54 and the sleeve 52 may be continuous, or alternatively, may be a series of spot welds spaced circumferentially around the outer periphery of the sleeve. Regardless, sleeve 52 defines a central axial opening 53 configured, and in particular sized and shaped, for receiving an end 32, 34 of the bar 30. Sleeve 52 further has a plurality of through holes 55 configured for receiving at least one, and preferably, a corresponding plurality of fasteners 51 to secure the hub 50 to the bar 30, as will be described. Flange 54 defines a plurality of through holes 56 formed and arranged in the same predetermined pattern as the through holes 46 of the wheel 42. Accordingly, the hub 50 can be attached to the wheel 42 of the weight subassembly 40 by at least one, and preferably, a corresponding plurality of fasteners, such as the externally-threaded bolts 48 and internally-threaded mating nuts 49.
Alternatively, as shown and described herein, the optional inner sleeve 60 is first inserted into the central opening 53 of the hub 50. Preferably, the inner surface of the sleeve 52 of the hub 50 and the outer surface of the inner sleeve 60 define a slight interference fit so that the inner sleeve is retained within the sleeve of the hub. The wheel 42 is then secured to the flange 54 of the hub 50 in the manner previously described. Next, the central opening 63 of the inner sleeve 60 is positioned around an end 32 of the bar 30 and the weight subassembly 40, including the hub 50 and the inner sleeve 60, is slid along the length of the bar to a desired position adjacent the end of the bar. The fasteners 51 are then threaded into the through holes 55 formed in the sleeve 52 of the hub 50 until the head of the lag bolt engages the outer surface of the inner sleeve 60. The inner sleeve is an elongate, annular cylinder made of a somewhat deformable and elastic material, such as polyethylene, polypropylene or polyvinyl chloride (PVC) pipe. Accordingly, as best shown in
As shown herein, the sleeve 52 of the hub 50 preferably has a total of eight (8) through holes 55 for receiving a corresponding eight (8) fasteners 51 with four (4) of the through holes being formed on each lateral side of the flange 54. In a particularly advantageous embodiment, the four (4) through holes 55 on each lateral side of the flange 54 are spaced circumferentially ninety degrees (90°) apart around the outer periphery of the sleeve 52 such that the holes are arranged in diametrically-opposed pairs. It is believed that the preferred arrangement of four (4) pairs of diametrically opposed through holes 55 and fasteners 51 provides a desirable degree of rigidity in the connection between the weight subassembly 40 and the bar 30 of the barbell assembly 20. In the event that the optional inner sleeve 60 is not used, the heads of the fasteners 51 engage the outer surface of the bar 30 at two (2) sets of diametrically-opposed locations on each lateral side of the flange 54. It is believed that under normal use conditions the eight fasteners 51 that attach each weight subassembly 40 to the bar 30 are sufficient for securing the weight subassembly, including the hub 50, against movement along the length of the bar, as well as rotation relative to the bar. Although hexagonal lag bolts 48, 51 and hexagonal nuts 49 have been shown in accompanying drawing figures, one of ordinary skill in the art will readily appreciate that thumb screws or the like may be substituted for the hexagonal lag bolts and hexagonal nuts may be replaced by wing nuts or the like.
As shown in
The foregoing detailed description of exemplary embodiments of the invention in conjunction with the accompanying drawing figures has shown and described a barbell assembly having impact absorbing weights that can be used on any exercise or competition surface in any location without damaging the surface in the event that the barbell assembly or one of the weights is dropped onto the surface. In addition, a barbell assembly according to the invention reduces noise and increases the safety of the user during use of the barbell assembly. Importantly, the barbell assembly includes at least one weight subassembly positioned and mounted adjacent each of the opposed ends of the bar. The weight subassembly comprises a weight and an inflatable component that is adapted to be attached to the weight and inflated.
In advantageous embodiments, the weight is a vehicle wheel having a predetermined pattern of through holes, such as a conventional trailer wheel, and the inflatable component is a vehicle tire, such as a conventional trailer tire, mounted on the trailer wheel. The barbell assembly further comprises a flange having at least one predetermined pattern of through holes that corresponds to the predetermined pattern of through holes formed on the vehicle wheel. At least one fastener inserted within the corresponding through holes secures the wheel to the flange. The flange may be affixed to a hub for securing the weight subassembly to the bar, with or without an optional inner sleeve. Alternatively, the flange may be affixed directly to the bar and the wheel of the weight sub assembly secured to the flange by the at least one fastener, as previously described.
In other exemplary embodiments, the barbell assembly further comprises a swivel assembly rotatably attached to at least one outer end of an Olympic bar. The swivel assembly comprises at least a U-shaped hook defining an opening, double-sided barrel bushing and a fastener. The bushing is inserted within a countersink formed in a cap of the outer end and the fastener is tightened to engage the threads of the fastener with the internally-threaded “tapped” end of the grip portion of the Olympic bar disposed within the outer end. As a result, the hook of the swivel assembly is free to rotate relative to both the outer end and the grip portion of the bar.
In other exemplary embodiments, the barbell assembly is utilized to perform a weight pushing exercise without causing damage to the surface on which the exercise is performed. An individual is positioned so as to push the barbell assembly by generating a driving force with his or her legs. Unlike conventional heavily weighted exercise equipment, such as a football sled, the inflatable component adapted to be attached around the periphery of the weight of each weight subassembly allows the barbell assembly to be pushed over the surface without causing damage.
In other exemplary embodiments, the barbell assembly is utilized to perform a weight pulling exercise without causing damage to the surface on which the exercise is performed. An individual is fitted with a harness and a sufficient length of a tether is attached to the harness and to the hook of a swivel assembly at each outer end of the bar. The individual is then positioned so as to pull the barbell assembly by generating a driving force with his or her legs. Unlike conventional heavily weighted exercise equipment, such as a football sled, the inflatable component adapted to be attached around the periphery of the weight of each weight subassembly allows the barbell assembly to be pulled over the surface without causing damage. The swivel assembly at each outer end of the bar allows the outer ends, including the weight subassemblies, to rotate freely relative to the hook of the swivel assembly.
In other exemplary embodiments, the barbell assembly is secured to an immovable fixture, such as a pole, post, tree, fence, or the like, by a sufficient length of a tether having a loop at each end. The tether is routed around the immovable fixture and around and/or through at least one of the weights of the weight subassemblies. The other end of the tether is routed through the opening defined by the stationary hook, or alternatively, the rotatable hook of the swivel assembly. The loops at the ends of the tether are then interlaced and locked together by a conventional lock.
Various exemplary embodiments have been shown and described herein. However, the present invention is not intended to be limited in any manner by the disclosed embodiments. Instead, the scope of the appended claims should be given the broadest reasonable interpretation consistent with the forgoing description and the accompanying drawing figures as understood and appreciated by those having at least ordinary skill in the relevant art.
This application is a continuation-in-part of U.S. application Ser. No. 14/071,632, filed on Nov. 4, 2013, which in turn is a continuation-in-part of U.S. application Ser. No. 13/707,749, filed on Dec. 7, 2012, the entire disclosures of which are incorporated herein by reference.
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Entry |
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Mehdi, How to make your own bumper plates on a budget, May 22, 2011, <http://web.archive.org/web/20110522050616/http://straighttothebar.com/articles/2007/09/how—to—make—your—own—bumper—pl/ >. |
Number | Date | Country | |
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20140200119 A1 | Jul 2014 | US |
Number | Date | Country | |
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Parent | 14071632 | Nov 2013 | US |
Child | 14227696 | US | |
Parent | 13707749 | Dec 2012 | US |
Child | 14071632 | US |