1. Field of the Invention
The present invention relates to a medical apparatus, and more particularly to a horizontal vibration apparatus.
2. Description of Related Art
A conventional medical apparatus in accordance with the prior art includes a pad and a coupler assembly connected to the pad. A transmission device is connected to the coupler assembly for providing an actuation force. A beating device is mounted on the pad for massaging a patient. The beating device includes multiple beating boards movably mounted thereon for slightly beating the patient. Therefore, the conventional medical machine is provided for preventing the patient from bedsore.
However, the conventional medical apparatus needs a lot of beating boards for corresponding to every part of the patient. The structure of the conventional medical apparatus is complex. The manufacturing fee of the conventional medical machine costs a lot. It is not possible for the beating boards exactly corresponding to every part of different patients. Furthermore, an unnecessary vibration is created due to the transmission device lacks a stabilizing mechanism. The unnecessary vibration causes the patient having an unpleasant feeling. The conventional medical apparatus is worn by the unnecessary vibration after a long time usage.
The present invention has arisen to mitigate and/or obviate the disadvantages of the conventional medical apparatus.
The main objective of the present invention is to provide an improved horizontal vibration apparatus for proving a smoothly horizontal vibration effect.
To achieve the objective, the horizontal vibration apparatus in accordance with the present invention comprises a stand and a vibration machine movably mounted on the stand. The vibration machine has at least one rail respectively mounted two sides thereof. The vibration machine has an actuating device mounted therein. The actuating device comprises a motor mounted on the stand, a vibrating seat mounted on the stand and relatively connecting to the motor, and an arm mounted on the vibrating seat and connected to the vibration machine. The motor provides for generating power and relatively driving the vibration seat. The vibrating seat provides for converting the power generated by motor to a horizontal vibration. The arm transmits the horizontal vibration from the vibrating seat to the vibration machine such that the vibration machine is horizontally moved relative to the stand. The actuating device has a decelerator mounted on the stand and positioned between the motor and the vibrating seat. The decelerator is relatively connected to the motor and the vibrating seat. The decelerator provides for adjusting the power generated by the motor and transmitting the adjusted power to the vibrating seat.
Two wheel assemblies are respectively mounted two sides of the stand. The two wheel assemblies are mirror images of each other. The two wheel assemblies respectively meshes with the at least one rail on the two sides of the vibration machine. Each wheel assembly has two wheel sets respectively mounted on two ends of the at least one rail. The two wheel sets of the same wheel assembly are mirror images of each other. Each wheel set has at least two wheels mounted therein. The at least two wheels of the same wheel set respectively mesh two reverse sides of the at least one rail for stabilizing the horizontal vibration of the vibration machine. Each wheel set has a rail mounted on the vibration machine, a first wheel seat mounted on the stand, and two second wheel seats mounted on the stand and respectively positioned on two sides of the first wheel seat. The first wheel seat has a vertical length longer than that of each of the two second wheel seats. The first wheel seat has an upper wheel rotatably mounted therein. Each second wheel seat has a lower wheel rotatably mounted therein. The upper wheel and the two lower wheels of the same wheel set are respectively positioned on two reverse sides of the rail for cooperatively securely meshing the rail.
In accordance with another aspect of the present invention, each wheel set has a wheel seat mounted on the stand and being adjacent to the distal end of the at least one rail. The wheel seat has a lower wheel rotatably mounted therein. The wheel seat has two ears upwardly extended therefrom and an upper wheel rotatably mounted between the two ears. The lower wheel is adjacent to the distal end of the at least one rail.
In accordance with another aspect of the present invention, each wheel set has a wheel seat mounted on the stand and being adjacent to the distal end of the at least one rail. Each wheel seat has a lower wheel rotatably mounted in a lower part thereof and an upper wheel rotatably mounted in an upper part thereof. The lower wheel is vertically aligned with the upper wheel.
In accordance with another aspect of the present invention, each wheel set has a first wheel seat and a second wheel seat mounted on the stand. The second wheel seat is adjacent to a distal end of the at least one rail. The first wheel seat has a vertical length longer than that of the second wheel seat. The first wheel seat has a first wheel rotatably mounted on a top thereof and the second wheel seat of the same wheel set has a second wheel rotatably mounted on a top thereof.
In accordance with another aspect of the present invention, each of the first wheel assembly and the second wheel assembly has a third wheel seat mounted on the stand and positioned between the two wheel sets. The third wheel seat has a same vertical length with that of the second wheel seat of each wheel set. The third wheel seat has a third wheel rotatably mounted on a top thereof for meshing a middle of the first rail.
In accordance with another aspect of the present invention, each wheel has a first wheel seat and a second wheel seat mounted on the stand. The first wheel seat is adjacent to a distal end of the at least one rail. The first wheel seat has a vertical length longer than that of the second wheel seat. The first wheel seat has a first wheel rotatably mounted on a top thereof and the second wheel seat has a second wheel rotatably mounted on a top thereof.
Further benefits and advantages of the present invention will become apparent after a careful reading of the detailed description with appropriate reference to the accompanying drawings.
Referring to the drawings in
The vibration machine 2 is able to assemble with a pad (not shown). The vibration machine 2 has an actuating device 3 mounted therein. The actuating device 3 has a motor 30 mounted on the stand 1 and a decelerator 32 mounted on the stand 1 and connected to the motor 30. The motor 30 is provided for generating a rotational force. The decelerator 32 is provided for hierarchically decreasing a rotation speed of the motor 30 to be several different speed levels. Furthermore, the decelerator 32 is also provided for raising the torsion of the force generated by motor 30. Between the motor 30 and the decelerator 32 has a first transmittal belt 33 communicated therewith. The actuating device 32 has a vibrating seat 31 mounted on the stand 1 and connected to the decelerator 32. A second transmittal belt 34 is disposed between the vibrating seat 31 and the decelerator 32 for communicating with the vibrating seat 31 and the decelerator 32. The vibrating seat 31 has an eccentric roller 310 centrally mounted thereon for generating vibration. An arm 311 is mounted on the vibrating seat 31 and connected to the vibration machine 2. Therefore, the motor 30 generates the rotation force to drive the decelerator 32 via the first transmittal belt 33, the decelerator 32 adjusts the rotation speed to drive the vibrating seat 31 via the second transmittal belt 34, and the vibrating seat 31 drives the eccentric roller 310 to convert from the rotation force to a horizontal vibration. The arm 311 transmits the horizontal vibration from the vibrating seat 31 to the vibration machine 2 with the pad. The vibration machine 2 is horizontally vibrated relative to the stand 1.
The first wheel assembly 4 and the second wheel assembly 5 are generally mirror images of each other. In the first wheel assembly 4, the first wheel assembly 4 has two wheel sets 41, 41 respectively mounted on two ends of the stand 1. The two wheel sets 41, 41 of the first wheel assembly 4 are generally minor images of each other. Each wheel set 41 has a rail 6 mounted on the vibration machine 2, a first wheel seat 411 mounted on the stand 1, and two second wheel seats 414, 414 mounted on the stand 1 and respectively positioned on two sides of the first wheel seat 411. The rail 6 is synchronously moved with the vibration machine 2. The rail 6 is moved relative to the stand 1. The first wheel seat 411 has a vertical length longer than that of each of the two second wheel seats 414, 414. The first wheel seat 411 has an upper wheel 412 rotatably mounted therein. Each second wheel seat 414 has a lower wheel 413 rotatably mounted therein. Each of the upper wheel 412 and the lower wheel 414 has a groove 415 annularly defined in a wheel surface thereof for correspondingly meshing the rail 6. The upper wheel 412 and the two lower wheels 413, 413 of the same wheel set 41 of the first wheel assembly 4 are respectively positioned on two reverse sides of the rail 6 for cooperatively securely meshing the rail 6. The two lower wheels 413, 413 are adjacent to two distal ends of the rail 6 and the upper wheel 412 is adjacent to a middle of the rail 6.
The motor 30 generates a force and the decelerator 32 adjusts the force for suiting different weights of different users and raising the torsion of the force generated by motor 30. The eccentric roller 310 and the vibrating seat 31 convert the force to a horizontal vibration. The arm 311 transmits the horizontal vibration from the vibrating seat 31 to the vibration machine 2 with the pad. The wheel sets 41, 41 of both the first wheel assembly 4 and the second wheel assembly 5 mesh the rail 6 such that the vibration machine 2 is stabilized and smoothly moved. Therefore, the present invention provides a horizontal vibration to achieve a massage therapy for massaging a human body.
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The first wheel assembly 4a is mounted on the first rail 61 and the second wheel assembly 5a is mounted on the second rail 62. In the first wheel assembly 4a, the first wheel assembly 4a has two wheel sets 41a, 41a respectively mounted on two ends of the first rail 61. The two wheel sets 41a, 41a of the first wheel assembly 4a are generally mirror images of each other. Each wheel set 41a of the first wheel assembly 4a has a wheel seat 411a mounted on the stand 1 and being adjacent to a distal end of the first rail 61. The wheel seat 411a of the first wheel assembly 4a has a lower wheel 413a rotatably mounted therein. The lower wheel 413a has a groove 415a annularly defined in a wheel face thereof for correspondingly meshing the first rail 61. The wheel seat 411a has two ears 414a upwardly extended therefrom. The wheel seat 411a of the first wheel assembly 4a has an upper wheel 412a rotatably mounted between the two ears 414a. The upper wheel 412a has a groove 415a annularly defined in a wheel face thereof for correspondingly meshing the first rail 61. The upper wheel 412a and the lower wheel 413a of the same wheel set 41a of the first wheel assembly 4a are respectively positioned on two reverse sides of the first rail 61 for cooperatively securely meshing the first rail 61. The lower wheel 413a is adjacent to the distal end of the first rail 61 and the upper wheel 412a is adjacent to a middle of the first rail 61.
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Although the invention has been explained in relation to its preferred embodiment, it is to be understood that many other possible modifications and variations can be made without departing from the spirit and scope of the invention as hereinafter claimed.