This disclosure relates to barbells, and more specifically to a barbell having polymer engaging structures positioned between a bar and sleeves of the barbell.
Aspects of the disclosure relate to a barbell that includes a bar having a first end portion and a second end portion, a first sleeve assembly including a first sleeve having a first axial bore with a first proximal bore portion, a first distal bore portion, and a first central bore portion extending between the first proximal bore portion and the first distal bore portion, where the first end portion of the bar is received through the first axial bore and extends through the first proximal bore portion and the first central bore portion to the first distal bore portion, a first proximal bushing received in the first proximal bore portion of the first sleeve, and a first distal bushing received in the first distal bore portion of the first sleeve. The first proximal bushing is fixed against axial movement with respect to the first sleeve assembly and has a first axial passage receiving the bar therethrough, where the first proximal bushing has a first outer surface engaging the first sleeve and a first inner surface engaging the bar within the first axial passage. The first distal bushing is fixed against axial movement with respect to the first sleeve assembly and has a first cavity. The barbell also includes a first barrel fixed to the first end portion of the bar, the first barrel having a cylindrical outer shape and received within the first cavity of the first distal bushing. The first distal bushing has a second outer surface engaging the first sleeve and a second inner surface engaging the first barrel within the first cavity. The first proximal bushing and the first distal bushing permit the first sleeve assembly to be freely rotatable around the bar and the first barrel, and the first outer surface and the first inner surface, the second outer surface, and the second inner surface are polymer surfaces.
According to one aspect, the bar further includes a first threaded projection extending outward from the first end portion. In one embodiment, the first barrel is fixed to the first end portion of the bar by a first fastener threaded onto the first threaded projection.
According to another aspect, the first axial bore has a first proximal opening and a first distal opening, and the first proximal bore portion extends inward from the proximal opening, and the first distal bore portion extends inward from the distal opening.
According to another aspect, the first sleeve assembly is freely rotatable with respect to the bar by the first proximal bushing rotating around the bar and the first distal bushing rotating around the first barrel.
According to another aspect, the first central bore portion has a first inner diameter that is smaller than the first proximal bore portion and the first distal bore portion.
According to a further aspect, the first barrel is fixed against axial movement with respect to the first distal bushing and against axial movement with respect to the bar, such that the bar is thereby also fixed against axial movement with respect to the first distal bushing.
According to yet another aspect, the first outer surface, the first inner surface, the second outer surface, and the second inner surface are formed of a same polymer material.
According to a still further aspect, the first axial bore has a first proximal opening and a first distal opening, and the first proximal bore portion is proximate to the proximal opening, and the first distal bore portion is proximate to the first distal opening.
According to an additional aspect, the barbell also includes a second sleeve assembly including a second sleeve having a second axial bore with a second proximal bore portion, a second distal bore portion, and a second central bore portion extending between the second proximal bore portion and the second distal bore portion, wherein the second end portion of the bar is received through the second axial bore and extends through the second proximal bore portion and the second central bore portion to the second distal bore portion, a second proximal bushing received in the second proximal bore portion of the second sleeve, and a second distal bushing received in the second distal bore portion of the second sleeve. The second proximal bushing is fixed against axial movement with respect to the second sleeve assembly and has a second axial passage receiving the bar therethrough, where the second proximal bushing has a third outer surface engaging the second sleeve and a third inner surface engaging the bar within the second axial passage. The second distal bushing is fixed against axial movement with respect to the second sleeve assembly and has a second cavity. The barbell further includes a second barrel fixed to the second end portion of the bar, the second barrel having a cylindrical outer shape and received within the second cavity of the second distal bushing. The second distal bushing has a fourth outer surface engaging the second sleeve and a fourth inner surface engaging the second barrel within the second cavity. The second sleeve assembly is freely rotatable with respect to the bar by the second proximal bushing rotating around the bar and the second distal bushing rotating around the second barrel, and the third outer surface, the third inner surface, the fourth outer surface, and the fourth inner surface are polymer surfaces.
According to another aspect, the first distal bushing includes a first bushing portion and a second bushing portion in abutting contact with each other. The first bushing portion has a first cylindrical wall with a first annular flange extending inward from the first cylindrical wall to define a first aperture at a proximal end of the first distal bushing, and the second bushing portion is positioned at a distal end of the first distal bushing. The first and second bushing portions combine to define the first cavity of the first distal bushing. In one configuration, the second bushing portion has a second cylindrical wall with a second annular flange extending inward from the second cylindrical wall to define a second aperture at the distal end of the first distal bushing, and the first cylindrical wall of the first bushing portion and the second cylindrical wall of the second bushing portion combine to define the second outer surface and the second inner surface, and to further define the first cavity as a cylindrical cavity. In another configuration, the first barrel engages the first annular flange and further engages the second bushing portion to resist axial movement of the first barrel with respect to the first distal bushing. In a further configuration, the second bushing portion is identical to the first bushing portion and is positioned in reverse orientation relative to the first bushing portion.
According to another aspect, the barbell includes a retaining member engaging a distal end of the first distal bushing to retain the first distal bushing in the first distal bore portion.
According to an additional aspect, the first sleeve has a first groove within the first proximal bore portion, and the first proximal bushing has a first engaging surface received within the first groove and engaging a surface of the first groove to retain the first proximal bushing within the first proximal bore portion.
According to yet another aspect, the polymer surfaces are all formed of polymer materials having a durometer hardness of 50 Shore A to 100 Shore A.
Additional aspects of the disclosure relate to a barbell that includes a first rotational body including a bar having a first end portion and a second end portion, a second rotational body mounted on the first end portion of the bar, a first rotational engagement structure connecting the first rotational body to the second rotational body to permit the second rotational body to be freely rotatable with respect to the first rotational body, such that the first rotational engagement structure constitutes all structures engaging both the first rotational body and the second rotational body, a third rotational body mounted on the second end portion of the bar, and a second rotational engagement structure connecting the first rotational body to the third rotational body to permit the third rotational body to be freely rotatable with respect to the first rotational body, such that the second rotational engagement structure constitutes all structures engaging both the first rotational body and the third rotational body. The second rotational body includes a first sleeve having a first bore receiving the first end portion of the bar, and the third rotational body includes a second sleeve having a second bore receiving the second end portion of the bar. All surfaces of the first rotational engagement structure engaging at least one of the first rotational body and the second rotational body and all surfaces of the second rotational engagement structure engaging at least one of the first rotational body and the third rotational body are formed of one or more polymer materials.
According to one aspect, the first rotational engagement structure includes at least a first bushing having a first surface engaging the first rotational body and a second surface engaging the second rotational body to permit rotation of the second rotational body relative to the first rotational body, and at least one of the first and second surfaces are formed of the one or more polymer materials. Additionally, the second rotational engagement structure includes at least a second bushing having a third surface engaging the first rotational body and a fourth surface engaging the third rotational body to permit rotation of the third rotational body relative to the first rotational body, and at least one of the third and fourth surfaces are formed of the one or more polymer materials. In one configuration, the first bushing is a first distal bushing located proximate to a distal end of the second rotational body and the first end portion of the first rotational body, and the second bushing is a second distal bushing located proximate to a distal end of the third rotational body and the second end portion of the first rotational body. In another configuration, the first bushing is a first proximal bushing located proximate to a proximal end of the second rotational body and spaced from the first end portion of the first rotational body, and the second bushing is a second proximal bushing located proximate to a proximal end of the third rotational body and spaced from the second end portion of the first rotational body. In a further configuration, the first rotational body includes a first cylindrical barrel connected to the first end portion of the bar and a second cylindrical barrel connected to the second end portion of the bar, the first and second cylindrical barrels having larger diameters than the bar. In this configuration, the first cylindrical barrel is engaged with the second surface of the first bushing to permit rotation of the second rotational body relative to the first cylindrical barrel, and the second cylindrical barrel is engaged with the fourth surface of the second bushing to permit rotation of the third rotational body relative to the second cylindrical barrel.
According to another aspect, the first rotational engagement structure includes at least a first proximal bushing formed of a first polymer material of the one or more polymer materials and a first distal bushing formed of a second polymer material of the one or more polymer materials, the first proximal bushing and the first distal bushing engaging the first rotational body and the second rotational body to permit rotation of the second rotational body relative to the first rotational body. Additionally, the second rotational engagement structure includes at least a second proximal bushing formed of a third polymer material of the one or more polymer materials and a second distal bushing formed of a fourth polymer material of the one or more polymer materials, the second proximal bushing and the second distal bushing engaging the first rotational body and the third rotational body to permit rotation of the third rotational body relative to the first rotational body.
According to a further aspect, the first rotational engagement structure includes a first rotor fixed to the first end portion of the bar and having a first cylindrical outer surface engaging an inner surface of the first bore to permit rotation of the second rotational body relative to the first rotational body, and the second rotational engagement structure includes a second rotor fixed to the second end portion of the bar and having a second cylindrical outer surface engaging an inner surface of the second bore to permit rotation of the third rotational body relative to the first rotational body.
According to yet another aspect, the first polymer material, the second polymer material, the third polymer material, and the fourth polymer material are the same.
According to a still further aspect, the one or more polymer materials each have a durometer hardness of 50 Shore A to 100 Shore A.
Further aspects of the disclosure relate to a barbell including a bar having a first end portion and a second end portion, a first sleeve assembly comprising a first sleeve having a first axial bore with a first proximal opening and a first distal opening, the first axial bore having a first proximal bore portion extending inward from the proximal opening, a first distal bore portion extending inward from the distal opening, and a first central bore portion extending between the first proximal bore portion and the first distal bore portion, a first proximal bushing received in the first proximal bore portion of the first sleeve, a first distal bushing received in the first distal bore portion of the first sleeve, a first barrel having a cylindrical outer shape and received within the first cylindrical cavity of the first distal bushing, a second sleeve assembly comprising a second sleeve having a second axial bore with a second proximal opening and a second distal opening, the second axial bore having a second proximal bore portion extending inward from the proximal opening, a second distal bore portion extending inward from the distal opening, and a second central bore portion extending between the second proximal bore portion and the second distal bore portion, a second proximal bushing received in the second proximal bore portion of the second sleeve, a second distal bushing received in the second distal bore portion of the second sleeve, and a second barrel having a cylindrical outer shape and received within the second cylindrical cavity of the second distal bushing. The bar has a first threaded projection extending outward from the first end portion and a second threaded projection extending outward from the second end portion. The first central bore portion has a first inner diameter that is smaller than the first proximal bore portion and the first distal bore portion, and the first end portion of the bar is received through the first axial bore and extends through the first proximal bore portion and the first central bore portion to the first distal bore portion. The second central bore portion has a second inner diameter that is smaller than the second proximal bore portion and the second distal bore portion, and the second end portion of the bar is received through the second axial bore and extends through the second proximal bore portion and the second central bore portion to the second distal bore portion. The first proximal bushing is fixed against axial movement with respect to the first sleeve assembly and has a first axial passage receiving the bar therethrough, and the first proximal bushing is formed of a first polymer material. The first distal bushing is fixed against axial movement with respect to the first sleeve assembly and has a first cylindrical cavity and a first aperture extending to the first inner cavity and receiving the first end portion of the bar therethrough, and the first distal bushing is formed of a second polymer material. The second proximal bushing is received in the second proximal bore portion of the second sleeve and fixed against axial movement with respect to the second sleeve assembly and has a second axial passage receiving the bar therethrough, and the second proximal bushing is formed of a third polymer material. The second distal bushing is received in the second distal bore portion of the second sleeve and fixed against axial movement with respect to the second sleeve assembly and has a second cylindrical cavity and a second aperture extending to the second inner cavity and receiving the second end portion of the bar therethrough, and the second distal bushing is formed of a fourth polymer material. The first barrel is fixed to the first end portion of the bar by a first fastener threaded onto the first threaded projection, and the first barrel is fixed against axial movement with respect to the first distal bushing and is fixed against axial and rotational movement with respect to the bar. The second barrel is fixed to the second end portion of the bar by a second fastener threaded onto the second threaded projection, and the second barrel is fixed against axial movement with respect to the second distal bushing and is fixed against axial and rotational movement with respect to the bar. The first sleeve assembly is freely rotatable with respect to the bar by the first proximal bushing rotating around the bar and the first distal bushing rotating around the first barrel, and the second sleeve assembly is freely rotatable with respect to the bar by the second proximal bushing rotating around the bar and the second distal bushing rotating around the second barrel.
According to one aspect, the first proximal bushing is formed entirely of the first polymer material, the first distal bushing is formed entirely of the second polymer material, the second proximal bushing is formed entirely of the third polymer material, and the second distal bushing is formed entirely of the fourth polymer material.
According to another aspect, the first polymer material, the second polymer material, the third polymer material, and the fourth polymer material are the same.
According to a further aspect, the first distal bushing includes a first bushing portion and a second bushing portion in abutting contact with each other, the first bushing portion having a first cylindrical wall with a first annular flange extending inward from the first cylindrical wall to define a first aperture at a proximal end of the first distal bushing, and the second bushing portion is positioned at a distal end of the first distal bushing, such that the first and second bushing portions combine to define the first cylindrical cavity of the first distal bushing. In one configuration, the second bushing portion has a second cylindrical wall with a second annular flange extending inward from the second cylindrical wall to define a second aperture at the distal end of the first distal bushing, and the first cylindrical wall of the first bushing portion and the second cylindrical wall of the second bushing portion combine to define the first cylindrical cavity. In another configuration, the second bushing portion is identical to the first bushing portion and is positioned in reverse orientation relative to the first bushing portion, and the first bushing portion and the second bushing portion are both formed of the second polymer material.
According to yet another aspect, the first sleeve has a first groove within the first proximal bore portion, and the first proximal bushing has an annular shoulder defining a first engaging surface received within the first groove and engaging a first surface of the first groove to retain the first proximal bushing within the first proximal bore portion and to resist axial movement of the first proximal bushing toward the first proximal opening with respect to the first sleeve. A distal end of the first proximal bushing engages a second surface of the first groove to resist axial movement of the first proximal bushing toward the first distal opening with respect to the first sleeve.
According to a still further aspect, the first polymer material, the second polymer material, the third polymer material, and the fourth polymer material each have a durometer hardness of 50 Shore A to 100 Shore A.
Still further aspects of the disclosure relate to a barbell that includes a bar assembly including a bar having a first end portion and a second end portion, a first sleeve assembly including a first sleeve having a first axial bore with a first proximal opening, a first proximal bore portion extending inward from the first proximal opening, a first distal bore portion, and a first central bore portion extending between the first proximal bore portion and the first distal bore portion, and a first proximal bushing received in the first proximal bore portion of the first sleeve and fixed against axial movement with respect to the first sleeve assembly. The first end portion of the bar is received through the first axial bore and extends through the first proximal bore portion and the first central bore portion to the first distal bore portion, the first central bore portion has a first inner diameter that is smaller than the first proximal bore portion, and the first proximal bore portion has a first groove spaced distally from the first proximal opening. The first proximal bushing has a first axial passage receiving the bar therethrough, a first outer surface engaging the first sleeve, and a first inner surface engaging the bar within the first axial passage. The first proximal bushing further has a first engaging surface received within the first groove and engaging a first surface of the first groove to retain the first proximal bushing within the first proximal bore portion and to resist axial movement of the first proximal bushing toward the first proximal opening with respect to the first sleeve. The first proximal bushing permits the first sleeve assembly to be freely rotatable with respect to the bar, and the first outer surface and the first inner surface are polymer surfaces.
According to one aspect, the first groove is an annular groove, and the first proximal bushing has an annular shoulder defining the first engaging surface.
According to another aspect, the first sleeve assembly is freely rotatable with respect to the bar by the first proximal bushing rotating around the bar.
According to a further aspect, a distal end of the first proximal bushing engages a second surface of the first groove to resist axial movement of the first proximal bushing toward the first distal bore portion with respect to the first sleeve.
According to yet another aspect, the barbell also includes a first distal bushing received in the first distal bore portion of the first sleeve and having a first cavity receiving a portion of the bar assembly, the first distal bushing further having second outer surface engaging the first sleeve and a second inner surface engaging the portion of the bar assembly. The first sleeve assembly is further freely rotatable with respect to the bar by the first distal bushing rotating around the portion of the bar assembly, and the second outer surface and the second inner surface are polymer surfaces.
Yet additional aspects of the disclosure relate to a barbell that includes a bar having a first end portion and a second end portion, a first sleeve assembly including a first sleeve having a first axial bore with a first proximal bore portion, a first distal bore portion, and a first central bore portion extending between the first proximal bore portion and the first distal bore portion, a first distal bushing received in the first distal bore portion of the first sleeve and fixed against axial movement with respect to the first sleeve assembly, the first distal bushing having a first cylindrical cavity and a first aperture extending to the first cavity, and a first barrel removably fixed to the first end portion of the bar, the first barrel having a cylindrical outer shape and received within the first cavity of the first distal bushing. The first end portion of the bar is received through the first axial bore and extends through the first proximal bore portion and the first central bore portion to the first distal bore portion, the first central bore portion having a first inner diameter that is smaller than the first distal bore portion. The first barrel has a larger outer diameter than the bar, and the first distal bushing has a first outer surface engaging the first sleeve and a second inner surface defining the first cylindrical cavity and engaging the first barrel within the first cylindrical cavity. The first distal bushing further engages the first barrel to fix the first barrel against axial movement with respect to the first distal bushing, and the first sleeve assembly is freely rotatable with respect to the bar by the first distal bushing rotating around the first barrel. The first outer surface and the first inner surface are polymer surfaces.
According to one aspect, the bar further includes a first threaded projection extending outward from the first end portion, and the first barrel is fixed to the first end portion of the bar by a first fastener threaded onto the first threaded projection.
According to another aspect, the first distal bushing includes a first bushing portion and a second bushing portion in abutting contact with each other, the first bushing portion having a first cylindrical wall with a first annular flange extending inward from the first cylindrical wall to define a first aperture at a proximal end of the first distal bushing. The second bushing portion is positioned at a distal end of the first distal bushing, and the first and second bushing portions combine to define the first cylindrical cavity of the first distal bushing. In one configuration, the second bushing portion has a second cylindrical wall with a second annular flange extending inward from the second cylindrical wall to define a second aperture at the distal end of the first distal bushing. In this configuration, the first cylindrical wall of the first bushing portion and the second cylindrical wall of the second bushing portion combine to define the first outer surface and the first inner surface, and to further define the first cylindrical cavity. In another configuration, the first barrel engages the first annular flange and further engages the second bushing portion to resist axial movement of the first barrel with respect to the first distal bushing. In a further configuration, the second bushing portion is identical to the first bushing portion and is positioned in reverse orientation relative to the first bushing portion.
Other aspects of the disclosure relate to a barbell that includes a first rotational body including a bar having a first end portion and a second end portion, a second rotational body mounted on the first end portion of the bar and including a first sleeve having a first bore receiving the first end portion of the bar, and a first rotational engagement structure connecting the first rotational body to the second rotational body to permit the second rotational body to be freely rotatable with respect to the first rotational body. The first rotational body, the second rotational body, and the first rotational engagement structure have a plurality of surface pairs engaging each other in surface-to-surface engagement with clearances greater than 0.001 inch, and each of the plurality of surface pairs engaging each other in surface-to-surface engagement with clearances greater than 0.001 inch includes at least one polymer surface.
According to one aspect, the first rotational engagement structure includes at least a first bushing engaging the first rotational body to form a first surface pair of the plurality of surface pairs engaging each other in surface-to-surface engagement with clearances greater than 0.001 inch and engaging the second rotational body to form a second surface pair of the plurality of surface pairs engaging each other in surface-to-surface engagement with clearances greater than 0.001 inch. At least one surface of the first surface pair and at least one surface of the second surface pair are polymer surfaces.
According to another aspect, the first rotational engagement structure includes at least a first proximal bushing and a first distal bushing. The first proximal bushing has a first surface engaging the first rotational body to form a first surface pair of the plurality of surface pairs engaging each other in surface-to-surface engagement with clearances greater than 0.001 inch, and a second surface engaging the second rotational body to form a first surface pair of the plurality of surface pairs engaging each other in surface-to-surface engagement with clearances greater than 0.001 inch. The first distal bushing has a third surface engaging the first rotational body to form a third surface pair of the plurality of surface pairs engaging each other in surface-to-surface engagement with clearances greater than 0.001 inch, and a fourth surface engaging the second rotational body to form a fourth surface pair of the plurality of surface pairs engaging each other in surface-to-surface engagement with clearances greater than 0.001 inch. The first surface, the second surface, the third surface, and the fourth surface are polymer surfaces.
According to a further aspect, each of the polymer surfaces is formed of a polymer material having a durometer hardness of 50 Shore A to 100 Shore A. In one configuration, the polymer materials of all of the polymer surfaces are the same.
According to yet another aspect, the barbell also includes a third rotational body mounted on the second end portion of the bar, the third rotational body including a second sleeve having a second bore receiving the second end portion of the bar, and a second rotational engagement structure connecting the first rotational body to the third rotational body to permit the third rotational body to be freely rotatable with respect to the first rotational body. The first rotational body, the third rotational body, and the second rotational engagement structure have a second plurality of surface pairs engaging each other in surface-to-surface engagement with clearances greater than 0.001 inch, and wherein each of the second plurality of surface pairs engaging each other in surface-to-surface engagement with clearances greater than 0.001 inch includes at least one polymer surface.
According to a still further aspect, the first rotational engagement structure includes a first rotor fixed to the first end portion of the bar and having a first cylindrical outer surface engaging an inner surface of the first bore to permit rotation of the second rotational body relative to the first rotational body. The first cylindrical outer surface and the inner surface of the first bore form a first surface pair of the plurality of surface pairs engaging each other in surface-to-surface engagement with clearances greater than 0.001 inch, and at least one of the first cylindrical outer surface and the inner surface of the first bore is a polymer surface.
Other aspects of the disclosure relate to a barbell that includes a bar having a first end portion and a second end portion, a first sleeve assembly including a first sleeve having a first axial bore with a first proximal bore portion, a first distal bore portion, and a first central bore portion extending between the first proximal bore portion and the first distal bore portion, a first proximal bushing received in the first proximal bore portion of the first sleeve and fixed against axial movement with respect to the first sleeve assembly, and a first rotor received in the first distal bore portion of the first sleeve and fixed against axial movement with respect to the first sleeve assembly, the first rotor fixed to the first end portion of the bar. The first end portion of the bar is received through the first axial bore and extends through the first proximal bore portion and the first central bore portion to the first distal bore portion. The first proximal bushing has a first axial passage receiving the bar therethrough and a first outer surface engaging the first sleeve and a first inner surface engaging the bar within the first axial passage. The first rotor has a cylindrical outer surface engaging the first sleeve, where the cylindrical outer surface is a polymer surface, and the first proximal bushing and the first rotor permit the first sleeve assembly to be freely rotatable around the bar and the first barrel.
Additional aspects of the disclosure relate to a barbell that includes a first rotational body including a bar having a first end portion and a second end portion, a first sleeve assembly including a first sleeve having a first axial bore with a first proximal bore portion and a first distal bore portion, a first proximal bushing received in the first proximal bore portion of the first sleeve, and a first distal bushing received in the first distal bore portion of the first sleeve and having a first cavity receiving a portion of the first rotational body located at the first end portion of the bar. The first end portion of the bar is received through the first axial bore and extends through the first proximal bore portion to the first distal bore portion. The first proximal bushing has a first axial passage receiving the bar therethrough and a first outer surface engaging the first sleeve and a first inner surface engaging the bar within the first axial passage. The first distal bushing has a second outer surface engaging the first sleeve and a second inner surface engaging the portion of the first rotational body within the first cavity. The first proximal bushing and the first distal bushing permit the first sleeve assembly to be freely rotatable around the first rotational body. At least one of the first outer surface and the first inner surface of the first proximal bushing and at least one of the second outer surface and the second inner surface of the first distal bushing are polymer surfaces.
Other aspects of the disclosure relate to a bushing that includes a cylindrical bushing body having cylindrical inner and outer surfaces, with the inner surface defining an axial passage through the bushing body, where the bushing body is configured to be inserted into a bore, and an engaging surface extending outward from the outer surface of the bushing body. The engaging surface is configured to be received within a groove in the bore when the bushing body is inserted into the bore, such that the engaging surface is configured to engage a surface of the groove to retain the bushing body within the bore.
According to one aspect, at least the inner surface and the outer surface are polymer surfaces. According to another aspect, the bushing is formed of a polymer material.
Other aspects of the disclosure relate to a bushing that includes a first bushing portion having a first cylindrical wall surrounding a first cavity, with a first annular flange extending inward from the first cylindrical wall to define a first aperture, and a second bushing portion having a second cylindrical wall surrounding a second cavity, with a second annular flange extending inward from the second cylindrical wall to define a second aperture. The second bushing portion is in abutting contact with the first bushing portion, such that the second bushing portion is positioned distally with respect to the first bushing portion, wherein the second annular flange is positioned at a distal end of the bushing, and the first annular flange is positioned at a proximal end of the bushing. The first cavity and the second cavity combine to define an inner cavity.
According to one aspect, the second bushing portion is identical to the first bushing portion and is positioned in reverse orientation relative to the first bushing portion.
According to another aspect, the bushing has an inner surface surrounding the cavity and an outer surface opposite the inner surface, and the inner surface and the outer surface are polymer surfaces. According to a further aspect, the bushing is formed of a polymer material.
Still other aspects of the disclosure relate to a method of assembling a barbell according to any configuration, aspect, or embodiment described above, including inserting a proximal bushing and/or a distal bushing into a bore of a sleeve, inserting a bar through the bore, and connecting the sleeve to the bar using a connecting structure, where the connecting structure and the proximal and/or distal bushings permit the bar to rotate with respect to the bar.
Other features and advantages of the disclosure will be apparent from the following description taken in conjunction with the attached drawings.
To allow for a more full understanding of the present disclosure, it will now be described by way of example, with reference to the accompanying drawings in which:
While this invention is susceptible of embodiments in many different forms, there are shown in the drawings and will herein be described in detail example embodiments of the invention with the understanding that the present disclosure is to be considered as an exemplification of the principles of the invention and is not intended to limit the broad aspect of the invention to the embodiments illustrated. In the following description of various example structures according to the invention, reference is made to the accompanying drawings, which form a part hereof, and in which are shown by way of illustration various example devices, systems, and environments in which aspects of the invention may be practiced. It is to be understood that other specific arrangements of parts, example devices, systems, and environments may be utilized and structural and functional modifications may be made without departing from the scope of the present invention.
General aspects of the present disclosure relate to a barbell that includes structures for reducing noise and vibration when the barbell is dropped from an elevated position.
The bar 12 has end portions 20, 22 that are connected to the sleeve assemblies 14, 16 and are received within the sleeves 30 of the sleeve assemblies 14, 16, as described in greater detail herein and a center portion 21 extending between the sleeve assemblies 14, 16. The bar 12 is configured for connection to fasteners 61 or other retaining members to the end portions 20, 22, and the bar 12 in
The center portion 21 and the end portions 20, 22 of the bar 12 in this embodiment have a circular cross-section shape and a substantially constant diameter and cross-sectional area over the entire combined axial length of the center portion 21 and the end portions 20, 22. It is understood that the projections 23 in
In the embodiment of
The proximal bushing 50 in the embodiment of
The proximal bushing 50 has an engaging surface 57 extending outward from the outer surface 52 proximate the distal end 56, which is provided in the form of an annular shoulder in the embodiment of
Additionally, in the embodiment of
The barrel 60 is fixedly connected to the distal end 24 of the bar 12 using a fastener 61 in the embodiment of
The distal bushing 70 engages the barrel 60 and the sleeve 30 from both axial directions in order to limit axial movement of the barrel 60 with respect to the sleeve 30, and thereby limit axial movement of the sleeve 30 with respect to the bar 12. The sleeve 30, the distal bushing 70, the barrel 60, and the bar 12 in the embodiment of
The end portion 20, 22 of the bar 12 extends through the aperture 76 of the first bushing portion 71 to connect to the barrel 60. The distal bushing 70 and the barrel 60 are not fixed against rotation relative to each other, and the barrel 60 can rotate together with the bar 12 within the cavities 74 of the distal bushing 70. It is noted that the flanges 75 of the bushing portions 71, 72 are formed as annular structures in the embodiment of
Additionally, in the embodiment of
In other embodiments, the barbell 10 may not include a barrel 60 that is separate from the bar 12 on one or both end portions 20, 22. For example, the bar 12 may include integrally formed barrels 60 or similar structures, or a combination of one integrally formed barrel 60 and one separate barrel 60 at the two end portions 20, 22. As another example, the distal bushing 70 may be configured to engage the bar 12 directly, and another structure (e.g., a retaining ring, split washer, end cap, etc.) may be used for axially fixing the bar 12 with respect to the sleeve 30. Still further embodiments may be used, such as the embodiment of
The sleeve 30 has a second bore portion or distal bore portion 45 extending inwardly/proximally from the distal opening 33 of the sleeve 30, having a larger inner width/diameter ID3 than the inner diameter ID1 of the central bore portion 42 (see
In an example embodiment, the proximal bushings 50 and the bushing portions 71, 72 of the distal bushings 70 are all made from polymer materials, which includes pure and mixed polymer materials, as well as polymer-matrix composite materials. These components may be manufactured using any of a variety of techniques or combinations of such techniques, including molding, casting, thermoforming, extrusion, machining, etc. The proximal bushings 50 and the bushing portions 71, 72 may all be made from the same polymer material, or some or all of these components may be made from different polymer materials, in various embodiments. The polymer material may be selected based on desirable properties, including strength, durability, low friction properties (e.g., coefficient of friction), and vibration/sound absorption or damping properties. In one embodiment, the polymer material may have a durometer hardness of 50 Shore A to 100 Shore A. One example of a suitable material that provides advantageous performance in this application is a urethane or polyurethane material. Other polymer materials may provide suitable and/or advantageous performance as well. Further, one or more surfaces of the barbell 10, including the inner and outer surfaces 78, 73 of the portions 71, 72 of the distal bushings 70, the inner surfaces 53 of the proximal bushings 50, the outer surface 62 of the barrel 60, and/or the outer surfaces of the end portions 20, 22 of the bar 12, may have a lubricant applied thereto in order to further reduce friction during rotation of the sleeves 30 with respect to the bar 12. The polymer material(s) of the bushings 50, 70 may be selected for lubricity properties and compatibility with potential lubricants, in such a configuration.
It is understood that the polymer bushings 50, 70 may have inserts, cores, or other internal components or portions made from other materials, such as metal, in one embodiment. For example, either or both of the bushings 50, 70 and/or components thereof may be made from metal pieces coated with a polymer material on one or more surfaces, e.g., a polymer piece with a metal core. Such bushings 50, 70 and/or components thereof are still considered to be formed of a polymer material as discussed herein. The advantages described herein are achieved in part by configuring the barbell so that, for each pair of surfaces of the barbell 10 that engage each other (particularly in moveable engagement) with clearances that are greater than or equal to a specific threshold, at least one of the pair of surfaces is a polymer surface, i.e., a surface formed of a polymer material. The specific threshold may be at least 0.001 inch in one embodiment, or 0.002 inch in another embodiment. In the embodiment of
In the embodiment of
It is also understood that components described herein as being formed of a polymer material, e.g., the bushings 50, 70 and/or components thereof, may be formed of different polymer materials. Accordingly, components described herein as being “formed of a polymer material” may be considered to be formed of one or more polymer materials, such that a first component is formed of a first polymer material, a second component is formed of a second polymer material, etc., which materials may be the same or different.
In the configuration shown in
In the embodiment of
To assemble the barbell 10 in the embodiment of
Various embodiments of barbells and components thereof have been described herein, which include various components and features. In other embodiments, the barbell may be provided with any combination of such components and features. It is also understood that in other embodiments, the various devices, components, and features of the barbell described herein may be constructed with similar structural and functional elements having different configurations, including different ornamental appearances.
The barbells and components thereof described herein provide benefits and advantages over existing barbells. For example, the barbells 10 shown in
Several alternative embodiments and examples have been described and illustrated herein. A person of ordinary skill in the art would appreciate the features of the individual embodiments, and the possible combinations and variations of the components. A person of ordinary skill in the art would further appreciate that any of the embodiments could be provided in any combination with the other embodiments disclosed herein. It is understood that the invention may be embodied in other specific forms without departing from the spirit or central characteristics thereof. The present examples and embodiments, therefore, are to be considered in all respects as illustrative and not restrictive, and the invention is not to be limited to the details given herein. When used in description of a method or process, the term “providing” (or variations thereof) as used herein means generally making an article available for further actions, and does not imply that the entity “providing” the article manufactured, assembled, or otherwise produced the article. Nothing in this specification should be construed as requiring a specific three dimensional orientation of structures in order to fall within the scope of this invention, unless explicitly specified by the claims. “Integral joining technique,” as used herein, means a technique for joining two pieces so that the two pieces effectively become a single, integral piece, including, but not limited to, irreversible joining techniques such as welding, brazing, soldering, or the like, where separation of the joined pieces cannot be accomplished without structural damage thereto. Additionally, the term “plurality,” as used herein, indicates any number greater than one, either disjunctively or conjunctively, as necessary, up to an infinite number. Accordingly, while the specific embodiments have been illustrated and described, numerous modifications come to mind without significantly departing from the spirit of the invention and the scope of protection is only limited by the scope of the accompanying claims.
This application is a continuation of, and claims priority to U.S. application Ser. No. 17/033,150, filed Sep. 25, 2020, which is a nonprovisional of, and claims priority to, U.S. Provisional Application No. 62/906,225, filed Sep. 26, 2019, and U.S. Provisional Application No. 62/983,135, filed Feb. 28, 2020, all of which prior applications are incorporated by reference herein in their entireties.
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Number | Date | Country | |
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20230277889 A1 | Sep 2023 | US |
Number | Date | Country | |
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62983135 | Feb 2020 | US | |
62906225 | Sep 2019 | US |
Number | Date | Country | |
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Parent | 17033150 | Sep 2020 | US |
Child | 17986427 | US |