The present disclosure relates to the field of tablet computer support, and more particularly, to an elevation working platform.
Tablet displays, tablet computers, etc., and associated supports are becoming increasingly popular in common families along with the developing of the society. An elevation working platform to support a tablet computer is typically disposed on a table or a desk in prior arts. Existing elevation working platforms provide a lifting resilience mostly through a mechanical spring or a torsion spring. A structure using support rods is typically utilized to enable the ascending or descending motion of the desk relative to an upper holder. The structure is complicated, and adjustment of the height of the desk may be bothering.
A technical problem to be solved by the present disclosure is to provide an elevation working platform with a simple structure and convenient height adjustment.
The technical solution of the present disclosure is to provide an elevation working platform comprising an elevation working platform body. The elevation working platform body having an upper support, a lower support and at least one group of X-shaped elevating components connected between the upper support and the lower support. Each group of X-shaped elevating components comprises a first support rod and a second support rod hinged to a central portion of each other to form an X-shape. The lower support comprises a first hinging seat fixedly connected thereto and a second hinging seat slidable relative to the lower support. The upper support comprises a third hinging seat fixedly connected thereto and a fourth hinging seat slidable relative to the upper support. A lower end of the first support rod is hinged to the first hinging seat. An upper end of the first support rod is hinged to the fourth hinging seat. A lower end of the second support rod is hinged to the second hinging seat. An upper end of the second support rod is hinged to the third hinging seat. The elevation working platform comprises an elastic component. A first end of the elastic component is connected between the two endpoints of the first support rod or the second support rod. A second end of the elastic component is connected to the lower support or the second hinging seat slidable relative to the lower support, and the elastic component bears at least a part of the weight of the upper support.
By employing the above structure, the elevation working platform has the following advantages compared to prior arts: The elevation working platform provides a support force by an elastic component to bear the weight of the upper support or bear a part of the weight of the upper support. Therefore the working platform can be held at any height with the benefit of a simple structure, a convenient height adjustment and a lower cost. Since the lateral position of the upper support would not be altered as the upper support moves vertically, the elevation working platform is considerably practical.
The elastic component is arranged between the lower support and the first support rod, the first end of the elastic component is hinged to the lower support, and the second end of the elastic component is hinged to the first support rod.
In some embodiments, the elastic component is arranged between the second hinging seat and the second support rod. The first end of the elastic component is hinged to the second hinging seat, and the second end of the elastic component is hinged to the second support rod.
In some embodiments, the elastic component is a compressed gas spring or a compressed mechanical spring.
In some embodiments, the elastic component is arranged between the lower support and the second support rod. The first end of the elastic component is hinged to the lower support, and the second end of the elastic component is hinged to the second support rod.
In some embodiments, the elastic component is arranged between the second hinging seat and the first support rod. The first end of the elastic component is hinged to the second hinging seat, and the second end of the elastic component is hinged to the first support rod.
In some embodiments, the elastic component is a stretch gas spring or a tension spring.
In some embodiments, a locking component to restrict the sliding of the second hinging seat is arranged on the lower support.
In some embodiments, the locking component arranged on the lower support to restrict the sliding of the second hinging seat comprises a first sliding rail connected to the lower support. The second hinging seat is slidably fitted on the first sliding rail. A plurality of positioning holes are arranged along a lengthwise direction on the second hinging seat. A box body is arranged on the lower support outside the second hinging seat. A movable pin having a free end to be inserted into or removed from the positioning holes is arranged in the box body, and a sliding plate to actuate the movable pin and remove the free end of the movable pin from the positioning holes is slidably fitted in the box body. As the locking component is operated, the sliding plate is pulled to slide within the box body. The sliding plate actuates the movable pin and removes the free end of the movable pin from the positioning holes. At this moment, the second hinging seat slides along the first sliding rail to adjust the height of the X-shaped elevating components. After the upper support ascends or descends to a certain height, the sliding plate is released and the free end of the movable pin is once again inserted into the positioning holes to restrict sliding of the second hinging seat.
In some embodiments, a locking component to restrict the sliding of the fourth hinging seat is arranged on the upper support.
The locking component can lock the X-shaped elevating components so as to fix the height of the desk plate of the X-shaped elevating component. The weight-bearing capabilities of the elevation working platform would be improved. The elastic force of the elastic components is surmounted by a hand to adjust the height of the upper support when the locking component is opened. After the height of the upper support has been adjusted, the locking component is released to restrict the sliding of the fourth hinging seat and lock up the X-shaped elevating components. Therefore, the elevation working platform has a simple structure and convenient height adjustment.
In some embodiments, the locking component arranged on the upper support to restrict the sliding of the fourth hinging seat comprises a second sliding rail connected to the upper support. The fourth hinging seat is slidably fitted on the second sliding rail, a plurality of positioning holes are arranged along a lengthwise direction on the fourth hinging seat. A box body is arranged on the upper support outside the fourth hinging seat. A movable pin having a free end to be inserted into or removed from the positioning holes is arranged in the box body, and a sliding plate to actuate the movable pin and remove the free end of the movable pin from the positioning holes is slidably fitted in the box body. As the locking component is operated, the sliding plate is pulled to slide within the box body. The sliding plate actuates the movable pin and removes the free end of the movable pin from the positioning holes. At this moment, the fourth hinging seat slides along the second sliding rail to adjust the height of the X-shaped elevating components. After the upper support ascends or descends to a certain height relative to the lower support, the sliding plate is released and the free end of the movable pin is once again inserted into the positioning holes to restrict sliding of the fourth hinging seat.
In some embodiments, a movable pin seat is in clearance fit within the box body. The movable pin is connected to the movable pin seat. A reset spring is arranged on the movable pin. An end of the reset spring is in contact with an inner wall of the movable pin seat. The other end of the reset spring is in contact with an inner wall of the box body. The free end of the movable pin is removed from the positioning holes when the reset spring is compressed. A first guiding slope is provided on the bottom of the movable pin seat. A second guiding slope fitted to the first guiding slope is arranged on the sliding plate, and the second guiding slope extrudes the first guiding slope to move the movable pin seat outwards against the resilience of the reset spring when the sliding plate slides to the outside of the box body. When pulling the sliding plate to slide within the box body, the second guiding slope pushes the first guiding slope on the bottom of the movable pin seat and causes the movable pin seat to move outwards against the resilience of the reset spring. At this moment, the free end of the movable pin on the movable pin seat is removed from the positioning holes, and the second hinging seat slides along the first sliding rail, or alternatively, the fourth hinging seat slides along the first sliding rail, to adjust the height of the upper support. After the height of the upper support has been adjusted to a certain degree, the sliding plate is released to reset the movable pin by the reset spring and restrict the sliding of the second and fourth hinging seat by inserting the free end of the movable pin into the positioning holes. Simultaneously, the first guiding slope of the movable pin seat pushes the second guiding slope to reset the sliding plate.
A dragline is connected on an outer end of the sliding plate. A dragline reset spring is arranged on the dragline. An end of the dragline reset spring is in contact with a side wall of the outer end of the sliding plate. The other end of the dragline reset spring is in contact with the inner wall of the box body. A lever is connected to the upper support, and the lever is connected to the outer end of the dragline.
In some embodiments, the at least one group of X-shaped elevating components comprises two groups of X-shaped elevating components arranged on two sides of the upper support, and the two groups of X-shaped elevating components are connected by a horizontal plate. The structure allows synchronized movement of the X-shaped elevating components on the two sides of the upper support, as well as enhanced mechanical strength and stability.
In some embodiments, a desk plate is connected to the upper support.
In some embodiments, the elevation working platform body comprises a keyboard holder connected to the upper support by a connecting plate.
1 upper support, 2 lower support, 3 first support rod, 4 second support rod, 5 first hinging seat, 6 second hinging seat, 7 third hinging seat, 8 fourth hinging seat, 9 elastic component, 9.1 gas spring, 9.2 spring, 10 desk plate, 11 horizontal plate, 12 keyboard holder, 13 lever, 14 first sliding rail, 15 second sliding rail, 16 positioning holes, 17 movable pin, 18 box body, 19 dragline reset spring, 20 reset spring, 21 movable pin seat, 22 first guiding slope, 23 sliding plate, 24 second guiding slope.
Detailed description of the present disclosure is provided hereinafter in combination with the accompanying figures and embodiments.
As shown in
During vertical movement of the upper support 1, the second hinging seat 6 and the fourth hinging seat 8 are slidable relative to the lower support 2 and the upper support 1 respectively, such that the X-shaped elevating components can be adjusted to lift or lower the upper support 1.
Embodiments of the present disclosure are not limited to the embodiments listed above.
In the first embodiment as shown in
A movable pin seat 21 is in clearance fit within the box body 18. The movable pin 17 is connected to the movable pin seat 21. A reset spring 20 is arranged on the movable pin 17. An end of the reset spring 20 is in contact with an inner wall of the movable pin seat 21. The other end of the reset spring 20 is in contact with an inner wall of the box body 18. The free end of the movable pin 17 is removed from the positioning holes 16 on the fourth hinging seat 8 when the reset spring 20 is compressed. A first guiding slope 22 is provided on the bottom of the movable pin seat 21. A second guiding slope 24 fitted to the first guiding slope 22 is arranged on the sliding plate 23, and the second guiding slope 24 extrudes the first guiding slope 22 to move the movable pin seat 21 outwards against the resilience of the reset spring 20 when the sliding plate 23 slides to the outside of the box body 18.
A dragline is connected on an outer end of the sliding plate 23. A dragline reset spring 19 is arranged on the dragline. An end of the dragline reset spring 19 is in contact with a side wall of the outer end of the sliding plate 23. The other end of the dragline reset spring 19 is in contact with the inner wall of the box body 18. A lever 13 is connected to the upper support 1, and the lever 13 is connected to the outer end of the dragline.
The at least one group of X-shaped elevating components comprises two groups of X-shaped elevating components arranged on two sides of the upper support 1, and the two groups of X-shaped elevating components are connected by the horizontal plate 11.
A desk plate 10 is connected to the upper support 1.
The elevation working platform body comprises a keyboard holder 12 connected to the upper support 1 by a connecting plate.
As shown in
The locking component 25 arranged on the lower support to restrict the sliding of the second hinging seat 6 comprises a first sliding rail 14 connected to the lower support 2. The second hinging seat 6 is slidably fitted on the first sliding rail 14. A plurality of positioning holes 16 are arranged along a lengthwise direction on the second hinging seat 6. A box body 18 is arranged on the lower support 2 outside the second hinging seat 6. A movable pin 17 having a free end to be inserted into or removed from the positioning holes 16 is arranged in the box body 18, and a sliding plate 23 to actuate the movable pin 17 and remove the free end of the movable pin 17 from the positioning holes 16 is slidably fitted in the box body 18.
A movable pin seat 21 is in clearance fit within the box body 18. The movable pin 17 is connected to the movable pin seat 21. A reset spring 20 is arranged on the movable pin 17. An end of the reset spring 20 is in contact with an inner wall of the movable pin seat 21. The other end of the reset spring 20 is in contact with an inner wall of the box body 18. The free end of the movable pin 17 is removed from the positioning holes 16 on the second hinging seat 6 when the reset spring 20 is compressed. A first guiding slope 22 is provided on the bottom of the movable pin seat 21. A second guiding slope 24 fitted to the first guiding slope 22 is arranged on the sliding plate 23, and the second guiding slope 24 extrudes the first guiding slope 22 to move the movable pin seat 21 outwards against the resilience of the reset spring 20 when the sliding plate 23 slides to the outside of the box body 18.
This application is a continuation of U.S. utility patent application Ser. No. 16/679,228, filed Nov. 10, 2019, now pending, which is a continuation of U.S. utility patent application Ser. No. 15/865,255 with a filing date Jan. 9, 2018, now granted as U.S. Ser. No. 10/517,390, issued Dec. 31, 2019, which is a continuation of International Patent Application No. PCT/CN2016/095619 with a filing date of Aug. 17, 2016, designating the United States, now expired, and further claims priority to Chinese Patent Application No. 201520728687.0 with a filing date of Sep. 18, 2015 and No. 201610378869.9 with a filing date of May 31, 2016. The content of the aforementioned applications, including any intervening amendments thereto, are incorporated herein by reference.
Number | Date | Country | |
---|---|---|---|
Parent | 17060086 | Oct 2020 | US |
Child | 17711704 | US | |
Parent | 16679228 | Nov 2019 | US |
Child | 17060086 | US | |
Parent | 15865255 | Jan 2018 | US |
Child | 16679228 | US | |
Parent | PCT/CN2016/095619 | Aug 2016 | US |
Child | 15865255 | US |