The present invention relates to resistance training equipment, and more particularly to an indoor rower that takes a restoring force of an elastic cord as resistance.
With increasing awareness in exercising and health care, an indoor rower is provided for people having a busy, fast-paced lifestyle to simulate the action of rowing a watercraft indoors.
A conventional indoor rower has a frame, a resistance assembly, a cable, a handle, a seat, and two stepping mounts. The frame has two opposite ends. The resistance assembly is disposed at one of the two opposite ends of the frame. The cable is wound in the resistance assembly. The handle is connected to an end of the cable and is disposed outside the resistance assembly. The seat is movably mounted to the frame. The two stepping mounts are respectively mounted to two sides of the frame. A user sits on the seat, steps on the two stepping mounts, and pulls the handle to simulate the action of watercraft rowing to work out. Simulating the action of watercraft rowing can promote cardiopulmonary function and circulation of the user.
The resistance assembly of the conventional indoor rower provides resistances in multiple manners such as magnetic resistance, air resistance, water resistance, or hydraulic oil resistance. The structure of the resistance assembly is complicated, and the resistance assembly is difficult to be assembled and costs high manufacturing expense.
To overcome the shortcomings of the resistance assembly of the conventional indoor rower, the present invention provides an indoor rower to mitigate or obviate the aforementioned problems.
The main objective of the present invention is to provide an indoor rawer that takes a restoring force as resistance and has a simple structure.
The indoor rower comprises a frame, a rolling assembly, and a winding assembly. The frame has a beam having a first end and a second end. The rolling assembly is disposed adjacent to the second end of the beam and has a rotatable wheel hub and a cable coiled around the wheel hub. The cable has a first cable end fastened to the wheel hub and a second cable end connected to a handle. The winding assembly has a first pulley set disposed adjacent to the first end of the beam, a second pulley set disposed at the second end of the beam, and an elastic cord coiled around the wheel hub, the first pulley set, and the second pulley set. The elastic cord has a first cord end being stationary and a second cord end being fastened to the wheel hub.
Other objects, advantages, and novel features of the invention will become more apparent from the following detailed description when taken in conjunction with the accompanying drawings.
With reference to
The frame 10 has a supporting pillar 11, a beam 12, an assembling mount 13, and a cover 14. The supporting pillar 11 has a top end. The beam 12 has a lengthwise direction, a first end, and a second end. The first end and the second end of the beam 12 are opposite each other in the lengthwise direction of the beam 12. The assembling mount 13 is mounted to the beam 12 and is disposed at the second end of the beam 12. The cover 14 is mounted to the beam 12. The cover 14 is disposed adjacent to the second end of the beam 12.
With reference to
The cable 23 is coiled around the first coiled section 221 of the wheel hub 22 and has a first cable end and a second cable end. The first cable end and the second cable end of the cable 23 are opposite to each other. The first cable end of the cable 23 is fastened to the first coiled section 221 of the wheel hub 22 and is able to spin with the wheel hub 22. The handle 24 is connected to the second cable end of the cable 23. The two guiding rollers 25 are rotatably mounted to the cover 14. Each one of the two guiding rollers 25 has a rolling axis parallel to the spinning axis 220 of the wheel hub 22. The second cable end of the cable 23 passes between the two guiding rollers 25 and then is connected to the handle 24.
The winding assembly 30 has a first pulley set 31, a second pulley set 32, and an elastic cord 33. The first pulley set 31 is connected to the supporting pillar 11. The first pulley set 31 is disposed adjacent to the first end of the beam 12 and below the beam 12. The first pulley set 31 has at least one pulley. The second pulley set 32 is connected to a bottom portion of the assembling mount 13 and is disposed at the second end of the beam 12. The elastic cord 33 has elasticity and may be a flexible rope or even a combination of both a flexible rope and a cotton rope. The elastic cord 33 is coiled around the second coiled section 222 of the wheel hub 22 and has a first cord end and a second cord end. The first cord end and the second cord end of the elastic cord 33 are opposite each other. The first cord end of the elastic cord 33 is stationary. In the embodiment of the present invention, the first cord end of the elastic cord 33 is fastened to the second pulley set 32. The first cord end of the elastic cord 33 may be optionally fastened to elsewhere. The second cord end of the elastic cord 33 is fastened to the second coiled section 222 of the wheel hub 22 and is able to spin with the wheel hub 22.
With reference to
With reference to
The cable 23 is wound up by the wheel hub 22, and the handle 24 connected to the cable 23 is drawn back toward the cover 14. A user reciprocately pulls the handle 24 and is reciprocately drawn by the elastic cord 33 and the cable 23 to simulate the action of watercraft rowing. The restoring force of the elastic cord 33 resists the user to pull the handle 24 and achieves resistance training. The indoor rower in accordance with the present invention utilizes the restoring force of the elastic cord 33 to drive the wheel hub 22 to rotate and make the wheel hub 22 retract the cable 23. The structure of the indoor rower in accordance with the present invention is simple, is convenient for assembling, and has the advantage of low manufacturing cost.
The resistance assembly 40 may be operated to adjust a training load of the indoor rower in accordance with the present invention. The adjusting stick 42 mounted through the tubular mount 41 is able to move toward or away from the flywheel 44. The adjusting stick 42 drives the resistance unit 43 to swing toward or away from the flywheel 44 to adjust a rotational speed of the flywheel 44.
With reference to
Even though numerous characteristics and advantages of the present invention have been set forth in the foregoing description, together with details of the structure and features of the invention, the disclosure is illustrative only. Changes may be made in the details, especially in matters of shape, size, and arrangement of parts within the principles of the invention to the full extent indicated by the broad general meaning of the terms in which the appended claims are expressed.