Rock climbing machine

Abstract

A rock climbing has a base placed flat on a bearing surface, a damping device mounted on the base, a pedal structure is connected to both sides of the damping device respectively and two rock climbing simulators upright fixed to the base. The two rock climbing simulators are mounted on both sides of the damping device respectively. Each rock climbing simulator is provided with a slide grip device, and each grip device is connected to a corresponding pedal structure. When the two pedal structures are trodden alternately, the corresponding grip devices reciprocate up and down, simulating the rock climbing action.

Claims

1. A rock climbing machine comprises: a base; a damping device mounted on the base, the damping device comprises a mounting rack fixed to base and a counterweight flywheel screwed in the mounting rack by a shaft; two pedal structures mounted on both sides of the damping device respectively; the two pedal structures are interlocked to the damping device by a transmission mechanism; each pedal structure comprises an oscillating arm with a front end pivoted on the mounting rack, the free end of the oscillating arm is provided with a pedal for the user to step on; the transmission mechanism comprises a first connecting bar with an end pivoted on the oscillating arm and a second connecting bar with an end fixed to a corresponding end of the shaft; the free ends of the first connecting bar and the second connecting bar are pivoted on each other; and two upright rock climbing simulators fixed to the base; a slide grip device is located at the top of each rock climbing simulator, and each grip device is connected to a corresponding pedal structure, and the grip device of each rock climbing simulator is located between the damping device and pedal; each rock climbing simulator comprises: an upright rail fixed to the base; the rail containing a longitudinal slideway with an outward opening, the grip device operable to slide up and down along the slideway during actuation; and a driving mechanism connected to a corresponding pedal structure; the driving mechanism comprises a first connecting bar and a second connecting bar; the first connecting bar is held in the slideway and operable to reciprocate against the rail; the first end of the second connecting bar is pivoted on the bottom of the first connecting bar, and the second end is pivoted on the corresponding pedal structure; the grip device is laterally fixed to the top of the first connecting bar.

2. The device defined in claim 1, wherein there are a plurality of rollers on the underside of the first connecting bar, so that the first connecting bar and grip device can perform straight reciprocation against the rail.

3. The device defined in claim 1, wherein the end of the second connecting bar of the transmission mechanism different from the first connecting bar of the transmission mechanism is radially fixed to the shaft.

4. The device defined in claim 1, wherein the section of the slideway is set as T-shape.

5. The device defined in claim 3, wherein the section of the slideway is set as T-shape.

Description

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

(1) FIG. 1 is a three-dimensional outside view of the present invention.

(2) FIG. 2 is a partial three-dimensional outside view of the present invention.

(3) FIG. 3 is a partial three-dimensional exploded diagram of rock climbing simulator of the present invention.

(4) FIG. 4 is a side view of the present invention.

(5) FIG. 5 is a schematic diagram of actuation of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

(6) FIGS. 1, 2, 3 and 4 show the preferred embodiments of rock climbing machine of the present invention, but the embodiments are for illustration only, the patent application is not limited to this structure. Said rock climbing machine comprises a base 10 placed flat on a bearing surface, a damping device 20 mounted on base 10, a pedal structure 30 is connected to both sides of the damping device 20 respectively, two rock climbing simulators 40 upright fixed to base 10. The two rock climbing simulators 40 are mounted on both sides of the damping device 20 respectively, a slide grip device 41 is located at the top of each rock climbing simulator 40, and each grip device 41 is connected to a corresponding pedal structure 30. When the two pedal structures 30 are pedaled alternately, driving the corresponding grip device 41 to move up and down, so as to simulate rock climbing actions.

(7) The damping device 20 comprises a mounting rack 21 fixed to base 10 and a counterweight flywheel 23 screwed in mounting rack 21 by shaft 22.

(8) Each pedal structure 30 comprises an oscillating arm 31 with front end pivoted on mounting rack 21, the oscillating arm 31 is a connecting lever structure, and its free end is provided with a pedal 32 for the user to step on. The oscillating arm 31 is connected to damping device 20 by a transmission mechanism 33. The transmission mechanism 33 comprises a first connecting bar 331 with end pivoted on oscillating arm 31 and a second connecting bar 332 with end radially fixed to a corresponding end of shaft 22. The free ends of the first connecting bar 331 and the second connecting bar 332 are pivoted on each other.

(9) Each rock climbing simulator 40 comprises a rail 42 upright or inclining forward fixed to base 10, the rail 42 contains a longitudinal slideway 43 with opening outward, as shown in FIG. 3. The rock climbing simulator 40 comprises a driving mechanism 44 connected to oscillating arm 31. The driving mechanism 44 comprises a first connecting bar 441 and a second connecting bar 442. The first connecting bar 441 is held in the slideway 43 and reciprocates against rail 42. The first end of the second connecting bar 442 is pivoted on the bottom of the first connecting bar 441 and the second end is pivoted on oscillating arm 31. The grip device 41 is laterally fixed to the top of the first connecting bar 441. There are plural rollers 443 on the underside of the first connecting bar 441, so as to reduce the friction between the first connecting bar 441 and rail 42, and to guarantee that the first connecting bar 441 and grip device 41 can perform straight reciprocating movement against rail 42. In addition, the grip device 41 of each rock climbing simulator 40 is located between damping device 20 and pedal 32.

(10) According to said structural composition design, the actuation of the present invention is described below. FIGS. 4 and 5 are the schematic diagrams of up-and-down rotary oscillation actuation of two pedal structures 30 of the rock climbing machine. The pedal 32 on one side is trodden downward, so that the pedal 32 on the opposite side rises upward. In this process, the two pedal structures 30 are interlocked to the damping device 20 by the transmission mechanism 33 respectively, the counterweight flywheel 23 of damping device 20 provides appropriate drag, this repeated actuation attains the effect of step exercise. The oscillating arm 31 swinging downward draws the first connecting bar 441 downward via the second connecting bar 442, so that the first connecting bar 441 and grip device 41 move down along the slideway 43 in rail 42. The oscillating arm 31 swinging upward on the opposite side underprops the first connecting bar 441 upward via the second connecting bar 442, so that the first connecting bar 441 and grip device 41 move up along the slideway 43 in rail 42. When the user treads pedal 32 and both hands grip the grip device 41 on both sides respectively, the grip devices 41 moving up and down alternately simulate the rock climbing action, so that the user attains the effect of step exercise and the effect of rock climbing simultaneously, not only providing double exercise effect, but also further coordinating the user's limbs, and it can be the preliminary training before formal rock climbing.

(11) In addition, as shown in FIGS. 4 and 5, when the oscillating arm 31 swings upward to the preset maximum tilt angle, forming the minimum included angle between the first connecting bar 331 and the second connecting bar 332 of transmission mechanism 33, the tilt angle of the second connecting bar 332 does not exceed the backward inclination angle of vertical angle, so as to evade driving dead point, the transmission mechanism 33 of the present invention can be interlocked to counterweight flywheel 23 most smoothly.

(12) It is noteworthy that the present invention can rehabilitate limbs. By means of reducing the damping effect provided by damping device 20, the damping effect provided by the global entity is adjusted to the patient's or senior's demand or limit according to the rehabilitation doctor's advice, the patient's or senior's demand for rehabilitation is met by moderate motion, so as to expand the range of use and added value of exercise equipments.