Adaptor for an indoor rowing machine

Abstract

A rowing machine can include a frame, a seat movably attached to the frame, the seat being configured to slide horizontally along the frame, a flywheel rotatably mounted to an end of the frame, a cable having a free end and an end attached to the flywheel, and an adapter assembly for compatibility with multiple oar or handle configurations.

Claims

1. An adapter for a rowing machine, the adapter comprising: a pair of arms pivotably mounted to one or more supporting members and connected to each other by a cable; a housing comprising: a horizontal track, a carriage mounted on the track and connected to the cable, the carriage being configured to move horizontally along the track in response a movement of the pair of arms; and a block comprising a channel and at least one pulley, the block being configured to mount on a rowing machine, wherein the carriage is connected to the cable and the cable passes through a pulley and the pulley is connected to the carriage by a second cable.

2. An adapter for a rowing machine, the adapter comprising: a pair of arms pivotably mounted to one or more supporting members and connected to each other by a cable; a housing comprising: a horizontal track, a carriage mounted on the track and connected to the cable, the carriage being configured to move horizontally along the track in response a movement of the pair of arms; and a block comprising a channel and at least one pulley, wherein the block is configured to mount on a rail of a conventional rowing machine.

3. An adapter for a rowing machine, the adapter comprising: a pair of arms pivotably mounted to one or more supporting members and connected to each other by a cable; a housing comprising: a horizontal track, a carriage mounted on the track and connected to the cable, the carriage being configured to move horizontally along the track in response a movement of the pair of arms; and a block comprising a channel and at least one pulley, wherein the housing further comprises at least two pulleys attached to an inner surface of the housing and a bungee cord passing through each of the pulleys, a first end of the bungee cord being attached to the inner surface and a second end being attached to the carriage.

4. A rowing machine comprising: a pair of arms pivotably mounted to one or more supporting members and connected to each other by a cable; a rail connected to a front end; a seat movably attached to the rail; a flywheel rotatably mounted to the front end; a chain having a free end and an end attached to the flywheel; a block mounted between the rail and the front end, the block comprising a channel extending below the rail and at least one pulley, wherein the free end of the chain is supported by the pulley and passes through the channel; and an adapter assembly comprising: a horizontal track, a carriage mounted on the horizontal track and connected to the cable, the carriage being configured to move horizontally along the track in response movement from both of the arms.

5. The rowing machine of claim 4, further comprising a pulley through which the cable passes, the carriage being connected to the cable through the pulley.

6. The rowing machine of claim 4, wherein the carriage is connected to the cable, and the cable passes through a pulley, wherein the pulley is connected to the carriage by a second cable.

7. The rowing machine of claim 4, wherein the arms are oars.

8. The rowing machine of claim 4, further comprising a swivel connector mounted on an end of each of the arms and attached to the cable, the swivel connector being configured to align the cable as each arm moves.

9. The rowing machine of claim 4, wherein the block is configured to mount on a rail of a conventional rowing machine.

10. The rowing machine of claim 4, wherein a height of the block is adjustable.

11. A method for retrofitting a rowing machine, the method comprising: attaching a block having a channel to a rail of a rowing machine, the rowing machine comprising: a frame; a seat movably attached to the rail, a flywheel rotatably mounted to a front end, a chain having an end attached to the flywheel and an end removably attached to a handle; and attaching a pair of arms and supporting members to a frame of the rowing machine, the pair of arms being pivotably mounted to one or more supporting members and connected to each other by a cable; removing the handle from the chain; attaching an adapter assembly to the frame below the rail, the adapter assembly comprising: a horizontal track, and a carriage mounted on the horizontal track and connected to the cable, the carriage being configured to move along the track in response to movement of the pair of arms; and attaching the chain to the transfer carriage.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Features and advantages of the claimed subject matter will be apparent from the following detailed description of embodiments consistent therewith, which description should be considered with reference to the accompanying drawings.

(2) FIG. 1 shows a conventional rowing machine according to the prior art.

(3) FIG. 2 shows an adapter attached to a conventional rowing machine, the adapter including outriggers, oars, oar locks, a power transfer carriage, cables, and pulleys.

(4) FIG. 3 shows a conventional rowing machine on a platform.

(5) FIG. 4 shows a partial view of the adapter installed on a conventional rowing machine.

(6) FIG. 5 shows a simplified representation of the movement direction and forces applied to a power transfer carriage.

(7) FIG. 6 shows a power transfer carriage connected to the chain of a conventional rowing machine.

(8) FIG. 7 shows a side view of the adapter of FIG. 2 including a path of a cable connecting the oar to the power transfer carriage through multiple pulleys.

(9) FIG. 8 shows a top down view of the adapter components of FIG. 2 including a path of a cable connecting the oar to the power transfer carriage through multiple pulleys.

(10) FIGS. 9A and 9B show an oarlock in isolation and attached to the oar.

(11) For a thorough understanding of the present disclosure, reference should be made to the following detailed description, including the appended claims, in connection with the above-described drawings. Although the present disclosure is described in connection with exemplary embodiments, the disclosure is not intended to be limited to the specific forms set forth herein. It is understood that various omissions and substitutions of equivalents are contemplated as circumstances may suggest or render expedient.

DETAILED DESCRIPTION

(12) The present disclosure relates to an adapter that transforms a conventional rowing machine (e.g., a Concept 2 indoor rowing machine model C, D, or E) into a rowing machine capable of switching between a single handle and a two-oar configuration. Installation of this adapter includes minimal modifications to a conventional rowing machine and enables a user to quickly switch between a single oar rowing motion and a two-oar rowing motion. FIG. 1 shows a conventional rowing machine of the prior art including a seat 2 mounted on a track 10 of a rail 12, a handle 6 connected to a flywheel 8, a monitor 4 for displaying rowing related metrics.

(13) FIG. 2 shows an adapter 100 attached to a conventional rowing machine 101. For clarity, the seat 2 and the monitor 4 are not shown. The adapter 100 includes outriggers 114,115 attached to the rail 12 of the conventional rowing machine 101, a pair of oars 102, 103, adapter oar locks 106, 107, a power transfer carriage 104 attached to a support track (not shown), and a series of cable segments 123-126 running through a series of pulleys 129.

(14) The adapter 100 uses a master link in the original chain 120, which provides the ability to quickly switch between sculling simulation (two separate oars) and the standard single-handle rowing machine configuration.

(15) The adapter 100 uses two oars 102, 103 cut down to a specified length with a specially designed adapter 118, 119 placed into the cut-off end of each oar 120, 103. The adapter 100 also allows the user the full range of motion within the sculling stroke and transfers the energy of the user's stroke back into the chain 120 (also referred to as a pull chain) of the conventional rowing machine 101 through a heavy gauge vinyl coated steel cable. Because the adapter 100 uses the sculling oarlocks 106, 107, it provides the user the experience of having to control the oar height throughout the stroke and allows the full range of vertical motion in the oar, which further simulates the action of real sculling.

(16) The heavy gauge steel cable allows the smooth range of motion of the oars and maintains a tight connection to the chain 120 through a series of pulleys 129, to direct the cable, and the power transfer carriage 104 located underneath the rail 12. The cable's ends are tied each to one of the oars 102, 103 so that the user must maintain pressure on each oar 102, 103 evenly throughout the stroke to pull the chain 120 of the conventional rowing machine 101.

(17) In some cases, the adapter 100 uses conventional sculling oars and oarlocks, however, these components may also be customized. For example, the length of the oar can be adjusted based on a rower's preference. In other cases, the oarlock may be selected to further restrain or free the movement of the oars during use.

(18) FIG. 2 also shows the path of the cable through the pulleys 129 of the adapter 100 to transfer the energy to the chain 120 of the conventional rowing machine 101. The power transfer carriage 104 uses a 2:1 mechanical disadvantage setup when pulling the chain 120. This mechanical disadvantage is offset by the 2:1 mechanical advantage conferred by the oars' pivot points.

(19) FIG. 3 and FIG. 4 show a conventional rowing machine 101 attached to a platform 152a, 152b using one or more rollers. This connection on the platform 152a, 152b allows the machine to move horizontally in directions generally indicated by an arrow 302.

(20) FIG. 5 shows a simple representation of how the power transfer carriage 104 is used. The cable (123-126) pulled by the oars 102, 103 pulls the power transfer carriage 104 to the left of the image along the direction of force. However, one end of the chain 120 is stationary so that for every 1 inch of movement of the power transfer carriage 104 to the left there are 2 inches of chain 120 pull. This mechanical disadvantage is directly offset by the choice of the pivot point (oarlock interface) location on the oars 102, 103. The portion of the oar 102, 103 that is outboard of the oarlock is roughly half the length of the inboard portion center on the oar's pivot point, giving the oar 102, 103 a 2:1 mechanical advantage and thus canceling out the disadvantage of the power transfer carriage 104. This setup allows a more compact design of the oars 102, 103 and the power transfer carriage 104, and still maintains about a 1:1 connection between the distance the oar handle moves and the amount the chain 120 moves. This maintains the same amount of total energy required for the same distance and speed of pull-chain movement, as compared to the original (unaltered) conventional rowing machine 101 single-handle rowing machine configuration.

(21) FIG. 6 shows the power transfer carriage 104 and its connection to the original Concept 2's chain 120. The chain 120 is lengthened via the master link and directed through the slide using a chain block 302. The chain block 302 is a 4-inch rail extension that is bolted to the existing rail 12 of the conventional rowing machine 101. The chain block 302 provides a through-the-rail path for the chain 120 (and chain extension) to pass to the underneath power transfer carriage 104. The power transfer carriage 104 is mounted on its rail system to keep it aligned and engaged with the user and the pull-chain system. This engagement and alignment helps to provide a smooth stroke and recovery movement to a user.

(22) FIG. 7 shows a side view of the adapter 100, which shows the path that the cable 123,125, 128 follows connecting the oar swivel 119 to the power transfer carriage 104 through the system of director pulleys 129. The power transfer carriage 104 additionally has a bungee cord system 402, which keeps tension on the cable 123,125, 128 and helps the power transfer carriage 104 return to its starting position during the rowing stroke recovery phase. FIG. 8 shows a top down view of the adapter components and the path of the steel cable through the system.

(23) FIGS. 9A and 9B show the oar locks 106, 107 used on the adapter. In particular, FIG. 9A shows the oarlock in isolation to highlight show 2 degrees of freedom required, and FIG. 9B shows the oar lock 107 installed on the oar 106.

INCORPORATION BY REFERENCE

(24) References and citations to other documents, such as patents, patent applications, patent publications, journals, books, papers, web contents, have been made throughout this disclosure. All such documents are hereby incorporated herein by reference in their entirety for all purposes.

EQUIVALENTS

(25) Various modifications of the invention and many further embodiments thereof, in addition to those shown and described herein, will become apparent to those skilled in the art from the full contents of this document, including references to the scientific and patent literature cited herein. The subject matter herein contains important information, exemplification, and guidance that can be adapted to the practice of this invention in its various embodiments and equivalents thereof.