This application claims the benefit of Taiwan application Serial No. 105115766, filed May 20, 2016, the subject matter of which is incorporated herein by reference.
The invention relates in general to a linear lifting device, and more particularly to a linear lifting device having a synchronous adjusting mechanism.
In comparison to the hydraulic linear motion element, the electric linear motion element, having a larger volume, can only be disposed on one side or two opposite sides of the lifting column and cannot be disposed at the center of the lifting column. However, when the electric linear motion element is disposed on one side of the lifting column, the pushing force is insufficient. Furthermore, the resistance caused by the lateral force directly affects the maximum output power, and the lifting column will take a longer time to ascend or descend.
When both sides of the lifting column have an electric linear motion element disposed thereon, the pushing force will be increased. However, displacement error (such as potential error or mechanic error) may easily occur if the two electric linear motion elements are not synchronized. Moreover, the lateral force will generate pendulum effect, making the lifting column to swing left and right or forward and backward. Therefore, it has become a prominent task for the industries to resolve the above problems.
The invention is directed to a linear lifting device. Through the coordination of a synchronous adjusting mechanism, two or multiple motion elements, despite having displacement error, still can move upward or downward synchronously, and pendulum effect caused by the lateral force can thus be reduced.
According to one embodiment of the present invention, a linear lifting device including a lifting column, a synchronous adjusting mechanism, a first motion element and a second motion element is provided. The lifting column has a fixed end and a movable end. The synchronous adjusting mechanism is disposed on the movable end and has a first force-bearing end and a second force-bearing end, which are respectively separated from the center of the synchronous adjusting mechanism by a rotating radius and remain at a synchronous state. The first motion element connects the first force-bearing end for generating a first force to push the first force-bearing end to move in a first force direction. The second motion element connects the second force-bearing end for generating a second force to push the second force-bearing end to move in a second force direction, such that the movable end can move with respect to the fixed end in a resultant force direction of the first force direction and the second force direction. In an embodiment, the lifting column has a linear extending direction, and the first motion element and the second motion element are substantially parallel to or form an angle with the linear extending direction of the lifting column.
According to another embodiment of the present invention, a linear lifting device including a lifting column, a synchronous adjusting mechanism and multiple motion elements is provided. The lifting column has a fixed end and a movable end. The synchronous adjusting mechanism is disposed on the movable end and has multiple force-bearing ends, which are respectively separated from the center of the synchronous adjusting mechanism by a rotating radius and remain at a synchronous state. The motion elements respectively connect the force-bearing ends for generating a force to push the force-bearing ends in a force direction, such that the movable end is pushed by the force to move with respect to the fixed end.
The above and other aspects of the invention will become better understood with regard to the following detailed description of the preferred but non-limiting embodiment(s). The following description is made with reference to the accompanying drawings.
Detailed descriptions of the invention are disclosed below with a number of embodiments. However, the disclosed embodiments are for explanatory and exemplary purposes only, not for limiting the scope of protection of the invention. In the following embodiments, two linear motion elements are used as an exemplification, the present invention can also be implemented by more than two linear motion elements. For example, two linear motion elements are disposed on each of the left and right sides of the lifting column; two linear motion elements are disposed on one side of the lifting column and a linear motion element is disposed on the other side of the lifting column; or four linear motion elements are respectively disposed on each of the front, rear, left and right sides of the lifting column. Besides, the linear motion element is only an example of embodiment, and other types (such as rotary, spiral or extendable) of motion elements can also be used the present invention, and the present invention does not have specific restrictions regarding the said design.
Refer to
In an embodiment, the first column 111 of the lifting column 110 is fixed (the bottom of the first column 111 is a fixed end 116), but the second column 112 can move upwards or downwards with respect to the first column 111 (the top 113 of the second column 112 is a movable end). In another embodiment (not shown), the second column 112 of the lifting column 110 is fixed, but the first column 111 can move upwards or downwards with respect to the second column 112. In another embodiment, the lifting column 110 can be composed of a fixed column and multiple movable columns, such that the height of the lifting column 110 is flexible and can be increased more and more, and the present invention does not have specific restrictions regarding the said design.
Apart from the above two operation methods, the present invention can use other linear lifting method, and is not subjected to specific restrictions. To avoid the first column 111 and the second column 112 tilting during the ascending or descending process, multiple gap pads 115, formed of such as rubber or springs, can be interposed between the first column 111 and the second column 112, such that the first column 111 and the second column 112 can maintain linear motion during the ascending or descending process. The gap pads 115 can absorb the lateral force generated the lifting column 110 during the ascending or descending process and avoid the lifting column 110 wobbling.
Refer to
The first linear motion element 130 and the second linear motion element 140 can be realized by two electric linear driving devices. When the push rod of the first linear motion element 130 is driven by electricity to generate a first force, the first moving shaft 124 of the synchronous adjusting mechanism 120 (that is, the first force-bearing end R1) is driven to move in a first force direction F1. Also, when the push rod of the second linear motion element 140 is driven by a motor to generate a second force, the second moving shaft 125 of the synchronous adjusting mechanism 120 (that is, the second force-bearing end R2) is driven to move in a second force direction F2.
In an embodiment, the first force direction F1 and the second force direction F2 are substantially parallel to the linear extending direction V of the lifting column 110 during the ascending or descending process. Refer to
Refer to
The central rotation shaft 121 is rotatably disposed on the movable end (that is, the top 113 of the second column 112). For example, the bearing 114 of the central rotation shaft 121 is disposed in the opening of the top 113, such that the central rotation shaft 121 can pass through the top 113 and rotate. The two ends of the central rotation shaft 121 have a first bushing 122 and a second bushing 123, which are respectively located on two opposite sides of a length extending direction L of the central rotation shaft 121.
That is, the first bushing 122 has a first arm 122a extended from the center of the central rotation shaft 121 in the first direction A1 (perpendicular to the length extending direction L of the central rotation shaft 121); the second bushing 123 has a second arm 123a extended from the center of the central rotation shaft 121 in the second direction A2 (perpendicular to the length extending direction L of the central rotation shaft 121). The first arm 122a has a rotating radius D with respect to the center of the central rotation shaft 121; the second arm 123a also has a rotating radius D with respect to the center of the central rotation shaft 121.
As disclosed above, the first direction A1 inverse to the second direction A2, and the rotating radius D of the first arm 122a is basically equivalent to the rotating radius D of the second arm 123a, such that the first arm 122a and the second arm 123a are respectively protruded from two opposite sides of the central rotation shaft 121 at an equal distance. That is, the first moving shaft 124 and the second moving shaft 125 are respectively located on two opposite sides of the central rotation shaft 121 through the first arm 122a and the second arm 123a.
The first moving shaft 124 is disposed on the first arm 122a of the first bushing 122 and is rotatably connected to the first linear motion element 130, and the first force-bearing end R1 is located on the first moving shaft 124, therefore the first linear motion element 130 can drive the first moving shaft 124 (that is, the first force-bearing end R1) to move in a first force direction F1. Moreover, the second moving shaft 125 is disposed on the second arm 123a of the second bushing 123 and is rotatably connected to the second linear motion element 140, and the second force-bearing end R2 is located on the second moving shaft 125, therefore the second linear motion element 140 can drive the second moving shaft 125 (that is, the second force-bearing end R2) to move in a second force direction F2.
It should be noted that the first force-bearing end R1 and the second force-bearing end R2 remain at a synchronous state. That is, when the first force and the second force have the same magnitude and are synchronized, the first force-bearing end R1 and the second force-bearing end R2 can concurrently move upward or downward. Meanwhile, the lifting column 110 receives twice the force, and therefore can move upward or downward at twice the speed to increase efficiency.
Suppose one linear motion element provides a force of 3500 N and moves at a speed of 7 mm/s. Then, two linear motion elements can generate twice the force (approximately 7000 N), and can move at twice the speed at a constant speed (approximately 14 mm/s). Therefore, the linear lifting device 100 of the present embodiment provides a larger force and moves at a faster speed, and therefore can better satisfy market requirements.
Refer to the linear lifting device 101 of
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According to the linear lifting device disclosed in above embodiments of the present invention, through the coordination of the synchronous adjusting mechanism, the displacement error generated by linear motion elements can be adjusted, such that two or more than two linear motion elements, despite having displacement error, still can be moved upward or downward synchronously, pendulum effect caused by the lateral force can be reduced, resistance of the lifting column during motion can be reduced, and the pushing force can be effectively increased. Besides, as the pushing force of the linear lifting device is increased, the upward or downward moving speed is also increased. Therefore, the linear lifting device has a larger pushing force and faster moving speed than the hydraulic linear motion element and better satisfies market requirements.
While the invention has been described by way of example and in terms of the preferred embodiment(s), it is to be understood that the invention is not limited thereto. On the contrary, it is intended to cover various modifications and similar arrangements and procedures, and the scope of the appended claims therefore should be accorded the broadest interpretation so as to encompass all such modifications and similar arrangements and procedures.
Number | Date | Country | Kind |
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105115766 | May 2016 | TW | national |