Patent Application
20190125606
The present invention relates generally to a health equipment, and more particularly to a device for producing a rhythmic movement.
A general bed is provided on a ground to be laid down by a user. However, when the user is in bed, a body portion contacting with the bed would be pressed under the user's weight, which may cause poor blood circulation.
For those who can act on their own, such pressure could be improved by turning over in bed. However, for those who cannot act autonomously (such as patients, those being bedridden, or those being in a persistent vegetative state), the prolonged pressure may occur bedsores.
In light of this, a swing device which could reciprocate is developed. When a user is on the swing device, a body of the user could swing along with the swing device, whereby to stimulate blood circulation. A conventional swing device, as disclosed in the Taiwan utility model patent M328860, is connected to a rotating bolt via a motor, and a sliding nut is disposed on the rotating bolt and is engaged with a sliding board, and a bearing member is disposed on the sliding board to be laid down by the user. Whereby, the bearing member could reciprocate along with the repeated forward and reverse rotation of the motor, stimulating the user's blood circulation.
In order to reciprocate the swing device, the motor thereof has to repeatedly rotate forward and reverse. However, when the motor is switched between forward and reverse rotation, an axle of the motor will temporary stop, so that the movement of the bearing member will be paused at the time that the motor is switched. As a result, the user cannot move rhythmically and stably. In all aspects, the conventional swing device still has room for improvements.
In view of the above, the primary objective of the present invention is to provide a device for producing a rhythmic movement, which could produce a periodic movement, facilitating the circulation of the human body.
The present invention provides a device for producing a rhythmic movement, including a base, a movable base, a first shaft, a second shaft, and a driving device. The movable base is disposed on the base, and moves relative to the base and reciprocates in a predetermined axial direction. The first shaft has a first end, and the second shaft has a first end pivotally connected to the first end of the first shaft. A second end of the first shaft is pivotally disposed on the movable base. A second end of the second shaft is pivotally disposed on the base. A pivot of the first end of the first shaft and the first end of the second shaft is located between the second end of the first shaft and the second end of the second shaft in the predetermined axial direction. The driving device is disposed on the base and is connected to the pivot of the first end of the first shaft and the first end of the second shaft, wherein the driving device repeatedly drives the pivot to move between a first position and a second position. When the pivot moves toward the first position, the second end of the first shaft is away from the second end of the second shaft in the predetermined axial direction, so that the movable base is driven to move toward a first direction in the predetermined axial direction. When the pivot moves toward the second position, the second end of the first shaft approaches to the second end of the second shaft, so that the movable base is driven to move toward a second direction in the predetermined axial direction, wherein the second direction is opposite to the first direction.
With the aforementioned design, the first shaft and the second shaft are driven by the driving device, so that the movable base could reciprocate in the predetermined axial direction, and the movable base could move rhythmically and stably. Whereby, a user on the device could move rhythmically along with the device for producing a rhythmic movement, facilitating the user's circulation and metabolism.
The present invention will be best understood by referring to the following detailed description of some illustrative embodiments in conjunction with the accompanying drawings, in which
As illustrated in
In the current embodiment, the base 10 includes a frame 12 and an adjusting device 14, wherein the frame 12 is long and rectangular, and has four legs 122 to be positioned on a bearing surface (such as ground). A top of the frame 12 includes a plurality of rails 124. Each of the rails 124 extends in a predetermined axial direction L. In the current embodiment, the rails 124 includes four rails 124, wherein each of the rails 124 extends in a long axial direction of the frame 12.
The adjusting device 14 is disposed on the frame 12, and includes at least one guiding shaft 16, a driving member 18, and an adjusting member 20. In the current embodiment, the at least one guiding shaft 16 includes two juxtaposed guiding shafts 16 from top down. There is an angle θ which is less than 90 degrees between a lone axial direction of the guiding shaft 16 and the predetermined axial direction L, wherein the driving device 26 and the shaft assembly 36 are located within an area corresponding to the angle θ. In the current embodiment, the driving member 18 includes two pulleys 182, a belt 184, and a motor 186, wherein the pulleys 182 are disposed on the frame 12 and are spaced from each other by a distance. The belt 184 fits around the pulleys 182, and are parallel to the long axial direction of the guiding shaft 16. A body of the motor 186 is fixed on the frame 12, and an axle of the motor 186 is connected to one of the pulleys 182. The adjusting member 20 fits around the guiding shafts 16 to be moved between a third position P3 shown in
The movable base 21 includes a movable frame 22 and a support plate 24 engaged with the movable frame 22. The movable frame 22 is long and rectangular, and has a plurality of wheels 222 provided at a bottom thereof, wherein the wheels 222 are respectively mounted on the rails 124 of the frame 12, whereby the movable base 21 could reciprocate relative to the base 10 in the predetermined axial direction L.
The driving device 26 is disposed on the frame 12 of the base 10, and includes a driving motor 28, a rotating member 32, and a connecting member which is a connecting shaft 35 as an example, wherein an axle of the driving motor 28 drives the rotating member 32 to rotate. In the current embodiment, a body of the driving motor 28 is disposed on the frame 12, and a first pulley 30 is disposed on the axle of the driving motor 28, wherein the axle of the driving motor 28 is perpendicular to a bottom surface of the support plate 24. The rotating member 32 is rotatably disposed on the frame 12, and includes a second pulley 322 and a rotating disk 324, wherein a diameter of the second pulley 322 is greater than a diameter of the first pulley 30, and a belt 34 is wound around the first pulley 30 and the second pulley 322. The rotating disk 324 is located above the second pulley 322 and is connected to the second pulley 322, whereby to coaxially rotate with the second pulley 322. A rotation center 32a of the rotating member 32 is parallel to the axle of the driving motor 28. The connecting shaft 35 has a first end 352 and a second end 354. In the current embodiment, the first end 352 of the connecting shaft 35 includes a connecting frame 352a. The second end 354 of the connecting shaft 35 is pivotally disposed on the rotating member 32, and is located on a side of the rotation center 32a of the rotating member 32. In other words, the second end 354 is adjacent to the rotation center 32a of the rotating member 32, and the second end 354 and the rotation center 32a are eccentric. In the current embodiment, the second end 354 of the connecting shaft 35 is pivotally disposed on the rotating disk 324.
The shaft assembly 36 includes a first shaft 40 and a second shaft 42, wherein the first shaft 40 has a first end 402, and the second shaft 42 has a first end 422. The first ends 402, 422 of the first shaft 40 and the second shaft are pivotally connected to each other, and are pivotally connected to the first end 352 of the connecting shaft 35. In the current embodiment, the first end 402 of the first shaft 40 and the first end 422 of the second shaft 42 are pivoted in the connecting frame 352a of the connecting shaft 35 via a pivot. Either of the first end 402 of the first shaft 40 or the first end 422 of the second shaft 42 is located above the first end of the other. In the current embodiment, the first end 402 of the first shaft 40 is located above the first end 422 of the second shaft 42. A second end 404 of the first shaft 40 is pivoted in a connecting frame 224 of the movable frame 22. A second end 424 of the second shaft 42 is pivotally disposed on the base 10. In the current embodiment, the second end 424 of the second shaft 42 is pivoted in the connecting frame 204 of the adjusting member 20 of the adjusting device 14. The pivot of the first end 402 of the first shaft 40 and the first end 422 of the second shaft 42 is located between the second end 404 of the first shaft 40 and the second end 424 of the second shaft 42 in the predetermined axial direction L.
When the axle of the driving motor 28 rotates, the rotating disk 324 of the rotating member 32 is driven to rotate, whereby to drive the second end 354 of the connecting shaft 35 to move along a path C in only one direction, wherein the path C is circular (as shown in
In addition, by changing a position of the adjusting member 20 via the motor 186 of the adjusting device 14, a range of the rhythmic movement could be changed.
When the motor 186 of the adjusting device 14 is controlled to move the adjusting member 20 to the third position P3, a pivot center 424a of the second end 424 of the second shaft 42 is apart from the rotation center 32a of the rotating member 32 by a first distance D1 (shown in
However, the control of the adjusting member 20 is not limited by the motor 186 and the guiding shaft 16. In practice, the adjusting member 20 could be disposed on a different position of the frame 12 to adjust the position of the second end 424 of the second shaft 42. In addition, the adjusting device 14 could be omitted, and the second end 424 of the second shaft 42 is pivotally disposed on the frame 12 of the body 10 instead. In such a case, the movable base 21 could reciprocate in the predetermined axial direction L as well.
As illustrated in
In the aforementioned embodiments, the driving device 26, 44 drives the eccentric 462 or the connecting shaft 35 to move via the driving motor 28, whereby to push the pivot of the first shaft 40 and the second shaft 42 to move between the first position P1 and the second position P2. In practice, the pivot could be driven in other ways, such as by using pneumatic cylinders or hydraulic cylinders.
As illustrated in
As illustrated in
As illustrated in
In conclusion, the device for producing a rhythmic movement of the present invention drives the shaft assembly via the driving device, so that the movable base could reciprocate in the predetermined axial direction, and the movable base could move rhythmically and stably. Whereby, a user on the device could move rhythmically, promoting the user's metabolism and circulation. The device for producing a rhythmic movement of the present invention could be applied to beds, seats, cushions and other equipment for people to rely on or lie down.
It must be pointed out that the embodiments described above are only some preferred embodiments of the present invention. All equivalent structures which employ the concepts disclosed in this specification and the appended claims should fall within the scope of the present invention.
