This non-provisional application claims priority under 35 U.S.C. ยง 119(a) on Patent Application No(s). 110113566 filed in Taiwan, R.O.C. on Apr. 15, 2021,the entire contents of which are hereby incorporated by reference.
1.Field of the Invention
The present disclosure relates to a lift buffering structure and more particular, to a lift buffering structure that can be used to replace conventional gas strut and oil strut.
2. Description of the Related Art
Different lift buffering devices, such as gas struts and oil struts, have been widely applied to machines and instruments that require buffered lifting, including medical equipment, industrial machines, ventilation windows of office buildings, and various kinds of furniture. The gas strut or the oil strut has a fluid filled therein to serve as a damper for buffering a piston in the gas or oil strut. The conventional gas strut and oil strut have some disadvantages. For example, the gas strut or the oil strut might spring up suddenly when releasing it from a braked or an anti-slipped state; the gas strut or the oil strut is uneasy to use because an operator has to laboriously retract the extended gas strut or oil strut; and, in the event of a gas leakage or oil leakage condition, the gas strut or the oil strut would not be able to provide braking and anti-slipping effects sufficient for supporting the required lifting length, resulting in degraded braking and anti-slipping performance of the gas strut or oil strut degrades over time. Further, the conventional gas strut and oil strut require high manufacturing costs because they must be completely sealed to prevent the fluid filled therein from leaking out.
To solve the problems in the conventional lift buffering devices, an objective of the present disclosure is to provide a lift buffering structure that can be used to replace the conventional gas strut and oil strut.
To achieve at least the above objective, the lift buffering structure according to the present disclosure includes a hollow column-shaped housing, a holding seat fixedly connected to an inner wall surface of the hollow column- shaped housing, an inner stem disposed in the hollow column-shaped housing and slidably extended through the holding seat, an elastic element having an end connected to the inner stem and another end to the holding seat to limit a travel stroke of the inner stem, an abutting unit located at one side of the holding seat opposite to the elastic element and having a width gradually downward reduced along a height direction of the hollow column-shaped housing, and an anti-slip unit connected to the inner stem and located between the abutting unit and the inner wall surface of the hollow column-shaped housing.
In an embodiment, surfaces of the abutting unit defining the gradually downward reduced width of the abutting unit are slant flat surfaces.
In an embodiment, the anti-slip unit includes a roller holder and at least one roller. The roller holder is fixedly connected to a lower end of the inner stem, and the roller has a rotational shaft rotatably connected to the roller holder. The roller has a rotational surface located corresponding to the abutting unit and the inner wall surface of the hollow column-shaped housing.
In an embodiment, the rotational surface of the roller has a knurled pattern formed thereon.
In an embodiment, the abutting unit includes two slant flat surfaces and the anti-slip unit includes two rollers; and rotational surfaces of the two rollers are located corresponding to the two slant flat surfaces.
In an embodiment, the lift buffering structure includes two abutting units, and the roller is formed on each of two end portions with a rotational surface. And, the two rotational surfaces on the roller are located corresponding to the two abutting units.
In an embodiment, the anti-slip unit is in the form of two beveled blocks respectively having a radially inward beveled surface.
In an embodiment, the surfaces of the abutting unit defining the gradually downward reduced width of the abutting unit are curved surfaces.
In the above embodiment, the anti-slip unit includes a roller holder and at least one roller. The roller holder is fixedly connected to a lower end of the inner stem, and the roller has a rotational shaft rotatably connected to the roller holder. And, the roller has a rotational surface located corresponding to the abutting unit and the inner wall surface of the hollow column-shaped housing.
In the above embodiment, the anti-slip unit can be in the form of two beveled blocks respectively having a radially inward beveled surface.
The lift buffering structure according to the present disclosure can be used to replace the conventional gas strut and oil strut. It is because the elastic force produced by the elastic element and the frictional force between the anti-slip unit and the abutting unit and the inner wall surface of the hollow column-shaped housing have the buffering and damping effects, making the lift buffering structure of the present disclosure durable and stable for use, free of air and oil leakage, capable of providing improved user operating feel, and producible with effectively reduced manufacturing costs.
To facilitate understanding of the objects, characteristics and effects of this present disclosure, embodiments together with the attached drawings for the detailed description of the present disclosure are provided. It is noted the present disclosure can be implemented or applied in other embodiments, and many changes and modifications in the described embodiments can be carried out without departing from the spirit of the disclosure, and it is also understood that the preferred embodiments are only illustrative and not intended to limit the present disclosure in any way.
As shown in
The hollow column-shaped housing 1 looks like a column and defines a height direction L. In the first embodiment, the hollow column-shaped housing 1 is square in cross section. However, it is noted the present disclosure is not particularly limited thereto. In other operable embodiments, the hollow column- shaped housing 1 can be a hollow column with round or any other polygonal cross section, or can even be a conical column or a pyramid column having a size- variable cross-sectional area.
The holding seat 2 is immovably connected to an inner wall surface 11 of the hollow column-shaped housing 1. More specifically, the holding seat 2 can be integrally formed with the hollow column-shaped housing 1 or be fixedly screwed to the inner wall surface 11 or in other possible means without being limited to any particular manner.
The inner stem 3 is disposed in the hollow column-shaped housing 1 and is slidably extended through the holding seat 2. The inner stem 3 can be round, oblong or other polygonal in cross section without being particularly limited.
The elastic element 4 has an end connected to the inner stem 3 and another end connected to the holding seat 2, so as to limit a travel stroke of the inner stem 3. In other words, when the inner stem 3 moves downward in the hollow column- shaped housing 1 along the height direction L, the elastic element 4 is compressed.
Please refer to
The abutting unit 5 is located at one side of the holding seat 2 opposite to the elastic element 4, and has a width that is downward reduced gradually along the height direction L of the hollow column-shaped housing 1. In other words, a distance between the abutting unit 5 and the inner wall surface 11 of the hollow column-shaped housing 1 is variable to gradually reduce toward the holding seat 2.
The anti-slip unit 6 is connected to the inner stem 3 and is located between the abutting unit 5 and the inner wall surface 11 of the hollow column-shaped housing 1.
When the elastic element 4 is in a non-compressed state, the anti-slip unit 6 is pressed at two lateral sides against the inner wall surface 11 and the abutting unit 5. When the inner stem 3 is moved downward along the height direction L of the hollow column-shaped housing 1, the anti-slip unit 6 has one lateral side keeping contact with the inner wall surface 11, and a frictional force between the anti-slip unit 6 and the inner wall surface 11 enables the inner stem 3 to lower stably. Meanwhile, the other lateral side of the anti-slip unit 6 is separated from the abutting unit 5 without contacting with the latter.
As shown in
In summary, the lift buffering structure 100 according to the present disclosure can be used to replace the conventional gas strut and oil strut. The elastic force of the elastic element 4 and the frictional force between the anti-slip unit 6 and the inner wall surface 11 and the abutting unit 5 to together achieve buffering and damping effects. The lift buffering structure 100 of the present disclosure has the advantages of durable for use, free of the problem of air leakage or oil leakage, even better operating feel, and reduced manufacturing cost.
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The lift buffering structure 100a is different from the lift buffering structure 100 in the first embodiment in that it includes an anti-slip unit 8 being two blocks respectively having a radially inward and downward beveled surface. The beveled surfaces of the anti-slip unit 8 are pressed against the abutting unit 5 and two outer surfaces of the anti-slip unit 8 are in frictional contact with the inner wall surface 11 to achieve the anti-slip effect.
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While the present disclosure has been described by means of specific embodiments, numerous modifications and variations could be made thereto by those skilled in the art without departing from the scope and spirit of the present disclosure set forth in the claims.
Number | Date | Country | Kind |
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110113566 | Apr 2021 | TW | national |