An exercise equipment, exercise equipment connector, and method of making same.
Exercise equipment can be free standing; however, it is desirable to be able to secure exercise equipment to a support such as the floor, wall, ceiling, or other exercise equipment for performance and safety reasons. For example, exercise equipment can move and/or tip over during use, and proper anchoring is essential for performance and safety.
There exists a need for anchoring exercise equipment quickly and effectively. Further, it is desirable that such connector is sufficiently strong and durable during long term use and operation of the exercise equipment, and properly anchor same.
An improved exercise equipment.
An improved exercise equipment anchor.
An improved exercise equipment connector.
An exercise equipment comprising or consisting of a member connected to connector or anchor.
An exercise equipment comprising or consisting of a vertical member connected to a connector or anchor.
An exercise equipment comprising or consisting of a vertical member connected to a three-sided connector or anchor.
An exercise equipment comprising or consisting of a vertical member connected to a three-sided connector or anchor comprising three finger connector portions bent outwardly from each side of the three-sided connector.
An exercise equipment anchor or connector comprising or consisting of a channel and at least finger connector portion.
An exercise equipment anchor or connector comprising or consisting of a three-sided channel and three finger connector portions.
An exercise equipment anchor or connector comprising or consisting of a three-sided channel and three finger connector portions each, respectively, extending outwardly from a side of the three-sided channel.
An exercise equipment anchor or connector comprising or consisting of a three-sided channel and three finger connector portions each, respectively, extending outwardly from a side of the three-sided channel at one end of the three-sided channel.
An exercise equipment anchor or connector comprising or consisting of a three-sided channel and three finger connector portions each, respectively, bent outwardly from a side of the three-sided channel at one end of the three-sided channel.
A method of making an exercising equipment anchor or connector, comprising or consisting of providing a flat metal sheet, and bending the flat metal sheet two times to create three-sided channel.
A method of making an exercising equipment anchor or connector, comprising or consisting of providing a flat metal sheet, and bending the flat metal sheet two times to create three-sided channel comprising three side portions connected together along bends in the three-side channel.
A method of making an exercising equipment anchor or connector, comprising or consisting of providing a flat metal sheet, bending the flat sheet two times to create a three-side channel comprising three side portions connected together along bends in the three-side channel.
A method of making an exercising equipment anchor or connector, comprising or consisting of providing a flat metal sheet, bending the flat sheet at two locations to create a three-side channel comprising three side portions connected together along bends in the three-side channel.
A method of making an exercising equipment anchor or connector, comprising or consisting of providing a flat metal sheet, bending the flat metal sheet two times to create three channel side portions connected together at the bends, and bending at least one side flange portion from the flat metal sheet.
A method of making an exercising equipment anchor or connector, comprising or consisting of providing a flat metal sheet, bending the flat metal sheet at a first location and a second location to create three channel side portions connected together at the bends, and bending the flat metal sheet at a third location to create at least one side flange connector portion from the flat metal sheet.
A method of making an exercising equipment anchor or connector, comprising or consisting of providing a flat metal sheet, bending the flat metal sheet two times to create three channel side portions connected together at the bends, and bending the three channel side portions to create three side flange connect portions so that each side flange connector portion is bent outwardly from each channel side portion.
A method of making an exercising equipment anchor or connector, comprising or consisting of providing a flat metal sheet, stamping the flat metal sheet to create a flat metal blank, and bending the flat metal blank to create the anchor or connector.
A method of making an exercising equipment anchor or connector, comprising or consisting of providing a flat metal sheet, stamping the flat metal sheet to create a flat metal blank, and bending the flat metal blank at multiple locations to create the anchor or connector.
A method of making an exercising equipment anchor or connector, comprising or consisting of providing a flat metal sheet, stamping the flat metal sheet to create a flat metal blank, and simultaneously bending the flat metal blank at multiple locations to create the anchor or connector.
A method of making an exercising equipment anchor or connector, comprising or consisting of providing a flat metal sheet, stamping the flat metal sheet to create a flat metal blank, and bending the flat metal blank at multiple locations in a particular sequence to create the anchor or connector.
A method of making an exercising equipment anchor or connector, comprising or consisting of providing a flat metal sheet, stamping the flat metal sheet to create a flat metal blank comprising a main blank portion and at least one finger blank portion, and bending the flat metal blank at multiple locations to create the anchor or connector.
A method of making an exercising equipment anchor or connector, comprising or consisting of providing a flat metal sheet, stamping the flat metal sheet to create a flat metal blank comprising a main blank portion and three finger blank portions, and bending the flat metal blank at multiple locations to create the anchor or connector.
A method of making an exercising equipment anchor or connector, comprising or consisting of providing a flat metal sheet, stamping the flat metal sheet to create a flat metal blank comprising a main blank portion and three finger blank portions positioned side-by side at one end of the main blank portion, and bending the flat metal blank at multiple locations to create the anchor or connector.
A exercise equipment 10 is shown in
The member 12 is provided with through holes 13 along the entire length of the member 12. The holes extend through both sets of opposed sides of the member 12 to allow connection with the connector 14 at different heights and different perpendicular orientations relative to a longitudinal axis of the member 12. This allows multiple members 12 to be connected together to make up a rack arrangement (e.g. four (4) members 12 connected together in a square or rectangular arrangement when viewing from top of rack).
The connector 14 can be connected to the floor F by bolt anchors 11, as shown in
The connector 14 by itself is shown in
The connector (e.g. anchor) can also be two-sided (e.g. adjacent or opposed sides) or four-sided (e.g. four sides with an open seam provided by bending the metal plate three times, or four sides with a closed seam, for example, by welding the seam closed after bending to enhance the strength of the connector). In a two sided connector (i.e. two adjacent sides removed, or two opposed sides removed), for example, a flat metal plate is bent into a channel with two sides being mostly removed along a length of the channel. A metal blank must be initially formed (e.g. by stamping a metal sheet) so that when bent a channel portion is provided at one end of the connector so that the two remaining sides are still connected together by the channel portion after the connector is created.
The connector 14 comprises three (3) flanges 16, 16, 16 extending outwardly from the connector 14. The flanges 16, 16, 16 are shown perpendicular (i.e. 90°) relative to the center vertical axis of the connector 14; however, the flanges 16, 16, 16 can be set at a different angle from that shown (e.g. 0° to 180° relative to the plane of each side channel portions 18, 20, 22). Further, the flanges 16, 16, 16 can be set at the same angle or different angles.
The opposed side channel portions 18 and 22 are each provided with a set of spaced apart through holes 24, 24, to allow connection with the member 12, for example, by a set of bolts 28, 28 (
The connector 14 can be made by a variety of methods using a variety of materials. For example, the method can include one or more steps of forming, bending, welding, machining, molding, injection molding, insert molding, or a combination thereof. Further, for example, the connector 14 can be made of metal, plastic, composite, or other material suitable for a particular application. For use in an exercise apparatus, metal can be a suitable material due to its relatively low cost and high strength.
The connector 14 can be made from a flat sheet of metal to create the flat metal blank 30. The flat metal blank 30 can be bent to create the connector 14.
As shown in
The step or steps of bending the flat metal blank 30 into the three sided channel 15 results in an integral high strength connection between the respective side panels 18, 20, 22 providing a high strength connector 14 suitable for use in assembling or anchoring exercise apparatus. In this arrangement, due to the bending step, the respective side panels 18, 20, 22 are also connected along their entire lengths and the length of the three sided channel 15, again increasing the integrity and high strength of the resulting connector 14.
The flanges 16, 16, 16 As also shown in
The step or steps of bending the flanges 16, 16, 16 relative the main portion 31 of the flat metal blank 30 results in integral high strength connections between the respective flanges 16, 16, 16 and main portion 31 of the flat metal blank 30 also enhancing the high strength of the high strength connector 14 suitable for use in assembling or anchoring exercise apparatus. In this arrangement, due to the bending step, the respective side panels 18, 20, 22 are also connected along their entire widths to the main portion 31 of the flat metal blank 30, again increasing the integrity and high strength of the resulting connector 14.
The integral bent connections 19, 21 between the side panels 18, 20, 22 of the three sided channel 15 and the integral bent connections 17 between the side panels 18, 20, 22 and the flanges 16, 16, 16 all contribute to the integrity and high strength of the box-like construction of the connector 14. Specifically, the bent nature of the walls of the integral bent connections 17, 19, 21 allow stress to flow around the bent connections 17, 19, 21, and then to be dispersed into the side panels 18, 20, 22 enhancing the high strength, performance, and longevity of the connector 14 under heavy work loads for a long period of time.
The radius of the integral bent connectors 17, 19, 21 can be configured to enhance the high strength of the connector 14. For example, the radius can be increased to enhance the flow of stress from the bent connectors to the side panels 18, 20, 22 and prevent stress risers. Further, the shape of the bent connectors 17, 19, 21 can be modified by changing the cross-sectional wall shape at the bend, again to customize stress flow for various purposes (e.g. integral bent connectors are made stronger at base of connector 15 to provide enhanced flexibility of members 12 to prevent cracking or wear). Thus, the thickness of the walls of the connector 14 can be varied and customized accordingly.
Method of Making
A metal connector 14 can be made, for example, by one of the following methods:
The steps in the above methods can occur simultaneously, or in a particular sequence. In addition to the above steps, the flat metal sheet or flat metal blank can, for example, be punched, cut, drilled, machined to provide connector (e.g. bolt, screw, anchor) holes. Further, the connector 14 can be hardened, coated (e.g. paint, powder coated), metal coated (e.g. chromed), treated (e.g. polished, beaded, surfaced, etched) to create a finished connector 14.
A method of making the connector 14 is illustrated in
As shown in
The flat metal blank 30 is then bent along fold lines 32, 32. Further, the flanges 16, 16, 16, are bent along fold lines, 34, 34, 34, and outwardly relative to the side channel portions 18, 20, 22. The order of bending, for example, can be by first bending the metal blank 30 for form the side channel portions 18, 20, 22, and then the side channel portions 18, 20, 22 are bent outwardly, or the bending occurs in the opposite order. Alternatively, the bending can occur simultaneously by using a stamping press that bends and/or cuts the edges of the flat metal blank is a single step or multiple step process.
The through holes 24, 26 can be made (e.g. punched, cut, drilled, machined) in the connector 14 before, after, or simultaneously with other connector forming or creating operations.
The flat metal plate blank 30 is formed or created to have the particular shape shown in
The flat metal blank 30 can be bent into the connector 30 by using a metal brake or by stamping.
Number | Name | Date | Kind |
---|---|---|---|
1214738 | Wolf | Feb 1917 | A |
1945925 | Stiefel | Feb 1934 | A |
2990590 | Graveley | Jul 1961 | A |
4611948 | Johnson | Sep 1986 | A |
5186571 | Hentzschel | Feb 1993 | A |
6209268 | Schmidt | Apr 2001 | B1 |
8833030 | Zimmerman | Sep 2014 | B2 |
8834057 | Adams, Jr. | Sep 2014 | B2 |
8839588 | Philbin | Sep 2014 | B2 |
20110107710 | Sias | May 2011 | A1 |
20130065738 | Henniger | Mar 2013 | A1 |
Number | Date | Country |
---|---|---|
2487239 | Jul 2012 | GB |
Number | Date | Country | |
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20140119811 A1 | May 2014 | US |
Number | Date | Country | |
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61721306 | Nov 2012 | US |