Magnetron mechanism of unpowered treadmill

Abstract

A magnetron mechanism of an unpowered treadmill contains: a driving body, a one-way transmission element, and a magnetron mechanism. The driving body includes a frame, a connection fence, a front wheel assembly, and a connection shaft. The one-way transmission element is mounted on the connection fence of the frame. The magnetron mechanism is fixed on the connection fence and includes a rotary shaft, a drive wheel, a driven wheel, a belt, a flywheel, a resistance element, and an adjustment unit. The resistance element has a pair of fixing sheets and multiple magnetic parts. Each of the multiple magnetic parts has a rotatable connection portion. The adjustment unit has a steel cable, an end of which is connected with the resistance element so that the steel cable pulls the resistance element to swing along the rotatable connection portion.

Claims

1. A magnetron mechanism of an unpowered treadmill comprising: a driving body including a frame, a connection fence formed on a peripheral side of the frame, a front wheel assembly fixed on a front end of the frame, and a connection shaft fixed on the front wheel assembly and extending to the connection fence; a one-way transmission element mounted on the connection fence of the frame; and a magnetron mechanism fixed on the connection fence of the frame, wherein the magnetron mechanism includes a rotary shaft, a drive wheel, a driven wheel, a belt, a flywheel, a resistance element, and an adjustment unit, the rotary shaft is connected on the one-way transmission element, the driven wheel is fitted with the connection shaft of the front wheel assembly of the driving body, the driven wheel is fitted with the rotary shaft, the belt is winded between the drive wheel and the driven wheel so as to drive the drive wheel and the driven wheel to rotate, wherein the flywheel is fitted with the rotary shaft, the resistance element has a pair of fixing sheets and multiple magnetic parts which are arranged parallelly, wherein each of the multiple magnetic parts has a rotatable connection portion formed on an end thereof so as to rotatably connect on the connection fence of the frame by mating with a resilient element, such that the pair of fixing sheets swings along the rotatable connection portion, and the resilient element pushes the pair of fixing sheets to move back to an original position automatically, wherein each pair of the multiple magnetic parts are oppositely arranged on the pair of fixing sheets, the adjustment unit has a steel cable, an end of which is connected with the resistance element so that the steel cable pulls the resistance element to swing along the rotatable connection portion.

2. The magnetron mechanism as claimed in claim 1, wherein the one-way transmission element is a one-way bearing.

3. The magnetron mechanism as claimed in claim 1 further comprising a press wheel arranged on an end of the rotary shaft so as to press the belt, thus obtaining tightness of the belt.

4. The magnetron mechanism as claimed in claim 1, wherein each of the multiple magnetic parts is a magnet.

5. The magnetron mechanism as claimed in claim 1, wherein the resilient element is a torsion spring.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a perspective view showing the assembly of a magnetron mechanism of an unpowered treadmill according to a preferred embodiment of the present invention.

(2) FIG. 2 is a perspective view showing the assembly of the magnetron mechanism of the unpowered treadmill according to the preferred embodiment of the present invention.

(3) FIG. 3 is a side plan view showing the assembly of a part of the magnetron mechanism of the unpowered treadmill according to the preferred embodiment of the present invention.

(4) FIG. 4 is a perspective view showing the assembly of a part of the magnetron mechanism of the unpowered treadmill according to the preferred embodiment of the present invention.

(5) FIG. 5 is a cross sectional view showing the assembly of a part of the magnetron mechanism of the unpowered treadmill according to the preferred embodiment of the present invention.

(6) FIG. 6 is a cross sectional view showing the operation of the magnetron mechanism of the unpowered treadmill according to the preferred embodiment of the present invention.

(7) FIG. 7 is another cross sectional view showing the operation of the magnetron mechanism of the unpowered treadmill according to the preferred embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

(8) The present invention will be clearer from the following description when viewed together with the accompanying drawings, which show, for purpose of illustrations only, a preferred embodiment in accordance with the present invention.

(9) With reference to FIGS. 1-5, a magnetron mechanism of an unpowered treadmill according to a preferred embodiment of the present invention comprises: a driving body 10, a one-way transmission element 20, and a magnetron mechanism 30.

(10) The driving body 10 includes a frame 11, a hand support (not shown) connected with a front portion of the frame 11, a connection fence 111 formed on a peripheral side of the frame 11, a front wheel assembly 12 and a rear wheel assembly (not shown) which are fixed on a front end and a rear end of the frame 12 respectively, a treadmill running belt (not shown) winded between the front wheel assembly 12 and the rear wheel assembly (not shown), a connection shaft 121 fixed on the front wheel assembly 12 and extending to the connection fence 111.

(11) The one-way transmission element 20 is mounted on the connection fence 111 of the frame 11 of the driving body 10, and the one-way transmission element 20 is a one-way bearing.

(12) The magnetron mechanism 30 is fixed on the connection fence 111 of the frame 11, and the magnetron mechanism 30 includes a rotary shaft 31, a drive wheel 32, a driven wheel 33, a belt 34, a press wheel 35, a flywheel 36, a resistance element 37, and an adjustment unit 38. The rotary shaft 31 is connected on the one-way transmission element 20, the driven wheel 32 has a first orifice 321 defined on a center thereof so as to fit with the connection shaft 121 of the front wheel assembly 12 of the driving body 10. The driven wheel 33 has a second orifice 331 defined on a center thereof so as to fit with the rotary shaft 31. The belt 34 is a timing belt winded between the drive wheel 32 and the driven wheel 33 so as to drive the drive wheel 32 and the driven wheel 33 to rotate. The press wheel 35 is arranged on an end of the rotary shaft 31 so as to press the belt 34, thus obtaining tightness of the belt 34.

(13) The flywheel 36 is made of aluminum alloy and is circular, and the flywheel 36 includes a third orifice 361 defined on a center thereof so as to fit with the rotary shaft 31. The resistance element 37 has a pair of fixing sheets 371 and multiple magnetic parts 372 which are arranged parallelly, wherein each of the multiple magnetic parts 372 has a rotatable connection portion 3711 formed on an end thereof so as to rotatably connect on the connection fence 111 of the frame 11 by mating with a resilient element 373, such that the pair of fixing sheets 371 swing along the rotatable connection portion 3711, and the resilient element 373 pushes the pair of fixing sheets 371 to move back to an original position automatically. Each pair of the multiple magnetic parts 372 are oppositely arranged on the pair of fixing sheets 371. In this embodiment, each of the multiple magnetic parts 372 is a magnet, and the resilient element 373 is a torsion spring. The adjustment unit 38 has a steel cable 381, an end of which is connected with the pair of fixing sheets 371 of the resistance element 37 so that the steel cable 381 pulls the pair of fixing sheets 371 of the resistance element 37 to swing along the rotatable connection portion 3711.

(14) As shown in FIGS. 6 and 7, after a user runs on the belt, the front wheel assembly 12 and the rear wheel assembly rotate to actuate the drive wheel 32 of the magnetron mechanism 30 to rotate with the connection shaft 121 of the front wheel assembly 12, the drive wheel 32 drives the driven wheel 32 to revolve via the belt 34, and the driven wheel 33 actuates the flywheel 36 to rotate via the rotary shaft 31, wherein the multiple magnetic parts 372 of the resistance element 37 and the flywheel 36 produce eddy currents by which resistance generates, the steel cable 381 of the adjustment unit 38 pulls the pair of fixing sheets 371 of the resistance element 37 of the resistance element 37 to swing along the rotatable connection portion 3711, and the resilient element 373 pushes the pair of fixing sheets 371 to move back to the original position automatically, thus adjusting the resistance. For example, the closer the magnetic member 372 of the resistance member 37 is to the flywheel 36, the greater the resistance generates. The farther the magnetic member 372 of the resistance member 37 is from the flywheel 36, the smaller the resistance generates, thus adjusting the resistance of the unpowered treadmill.

(15) The rotary shaft 31 of the magnetron mechanism 30 is connected on the one-way transmission element 20, so when the user stops running on the unpowered treadmill, the unpowered treadmill is stopped immediately by using the one-way transmission element 20 without leaving inertia force, thus preventing the user falling from the unpowered treadmill and enhancing using safety.

(16) The magnetron mechanism of the unpowered treadmill has following advantages:

(17) The magnetron mechanism is simplified to reduce fabrication cost, and the magnetron mechanism 30 and the one-way transmission element 20 are assembled, removed, and maintained easily and quickly, thus saving labor consumption and assembling time.

(18) While various embodiments in accordance with the present invention have been shown and described, it is clear to those skilled in the art that further embodiments may be made without departing from the scope of the present invention.