The present invention relates to a seating apparatus. Particularly, the invention relates to a seat and back support for a frame or seating chassis that is ergonomically designed to provide postural support and weight distribution through movement.
The present invention is a seating apparatus designed to remedy some of the problems associated with prolonged sitting in an upright position, such as pain and discomfort. Manufacturers of office seats have recognized that pain and discomfort associated with prolonged, upright sitting can lead to high medical costs and reduced employee productivity.
Sitting discomfort has been widely investigated and has led to the development of seating systems that enhance the posture and comfort of individuals who sit for long periods of time. These seating systems offer ergonomic solutions based on the premise that comfort is not achieved from a single, static position, but required changes in posture through motion. However, these seating systems are complex, expensive to produce, and are not adaptable to a variety of seating chassis.
What is needed, therefore, is an ergonomically designed seating apparatus that is simple, cost-effective, and adaptable for use in a variety of seating chassis.
Accordingly, it is an object of the present invention to provide a seating apparatus that offers postural support for a user seated in an upright position.
A further object of the present invention is to provide a seat and a back support that may be used separately or together.
Another object of the present invention is to provide a seating apparatus that is adaptable for use in a variety of seating chassis, such as a wheelchair, automobile, stadium, auditorium, or airline seat.
Still another object of the present invention is to provide a seat that permits articulated movement of a user's pelvis while seated in an upright position.
A yet further object of the present invention is to provide a back support that permits flexibility of a user's spinal column while seating in an upright position.
These and other objects of the present invention are achieved by providing an ergonomically designed apparatus having a seat and a backrest. The seat includes a seat frame adapted to be secured to a chassis, a seat support pivotally connected to the seat frame such that the seat support is capable of pivotal tiling about a transverse horizontal axis relative to the seat frame, and at least one first resilient member positioned between the seat frame and the seat support permitting resilient relative pivotal tilting between the seat frame and the seat support. The backrest includes a back frame adapted to be secured to the chassis, the back frame includes two parallel bars; a lumbar support connected to the back frame at each of the two parallel bars; a back support pivotally connected to the lumbar support such that the back support is capable of pivotal tilting about a second transverse horizontal axis relative to the back frame, the two parallel bars aligning parallel to and on either side of the second transverse horizontal axis such that the second transverse horizontal axis is between the two parallel bars and the back support extends above the two parallel bars; and at least one second resilient member positioned along surfaces of the lumbar support and the back support permitting resilient relative pivotal tilting between the lumbar support and the back support. The back frame and the seat frame are connected to and removable from a wheelchair frame having at least three wheels, wherein a position of the second transverse horizontal axis is adjustable relative to the wheelchair frame from front to back.
In some embodiments, the seat frame includes at least one telescoping member arranged such that the seat frame is size-adjustable in at least one dimension. In other embodiments, the seat frame includes a plurality of telescoping members arranged such that the seat frame is size-adjustable in at least one dimension.
In some embodiments, the back frame includes at least one telescoping member connected to each of the two parallel bars and arranged such that the back frame is size-adjustable in at least one dimension. In other embodiments, the back frame includes a plurality of telescoping members connected to each of the two parallel bars and arranged such that the back frame is size-adjustable in at least one dimension.
In some embodiments, the back support includes at least one pivot arm extending below the second transverse horizontal axis configured to limit the pivotal range of motion of the back support. In other embodiments, the lumbar support includes at least one pivot block configured to interact with the at least one pivot arm.
In some embodiments, each of the seat support, the lumbar support, and the back support are formed of a rigid material, have a contoured shape ergonomically designed to correspond to the human body, and have a plurality of ventilation holes.
In an alternative embodiment of the present invention, an ergonomically designed seating apparatus having a seat and a backrest is provided. The seat includes a seat frame adapted to be secured to a chassis, a seat support pivotally connected to the seat frame such that the seat support is capable of pivotal tiling about a first transverse horizontal axis relative to the seat frame, and at least one first resilient member positioned between the seat frame and the seat support permitting resilient relative pivotal tilting between the seat frame and the seat support. The backrest includes a back frame adapted to be secured to the chassis, a lumbar support connected to the back frame, a back support pivotally connected to the lumbar support such that the back support is capable of pivotal tilting about a second transverse horizontal axis relative to the back frame, at least one second resilient member positioned along adjacent surfaces of the lumbar support and the back support permitting resilient relative pivotal tilting between the lumbar support and the back support, at least one pivot arm connected to the back support, and at least one pivot block connected to the lumbar support. The at least one pivot arm is configured to limit the pivotal range of motion of the back support, and the at least one pivot block is configured to interact with the at least one pivot arm.
In some embodiments, the seat frame includes at least one telescoping member arranged such that the seat frame is size-adjustable in at least one dimension.
In some embodiments, the back frame includes at least one telescoping member arranged such that the back frame is size-adjustable in at least one dimension.
In some embodiments, each of the seat support, the lumbar support, and the back support are formed of a rigid material, have a contoured shape ergonomically designed to correspond to the human body, and have a plurality of ventilation holes.
In another embodiment of the present invention, a wheelchair having a wheelchair chassis, a seat, and a backrest is provided. The seat includes a seat frame adapted to be secured to the wheelchair chassis, a seat support pivotally connected to the seat frame such that the seat support is capable of pivotal tiling about a first transverse horizontal axis relative to the seat frame, and at least one first resilient member positioned between the seat frame and the seat support permitting resilient relative pivotal tilting between the seat frame and the seat support. The backrest includes a back frame adapted to be secured to the wheelchair chassis, a lumbar support connected to the back frame, a back support pivotally connected to the lumbar support such that the back support is capable of pivotal tilting about a second transverse horizontal axis relative to the back frame, and at least one second resilient member positioned along adjacent surfaces of the lumbar support and the back support permitting resilient relative pivotal tilting between the lumbar support and the back support.
In some embodiments, the seat frame includes at least one telescoping member arranged such that the seat frame is size-adjustable in at least one dimension. In other embodiments, the seat frame includes a plurality of telescoping members arranged such that the seat frame is size-adjustable in at least one dimension.
In some embodiments, the back frame includes at least one telescoping member arranged such that the back frame is size-adjustable in at least one dimension. In other embodiments, the back frame includes a plurality of telescoping members arranged such that the back frame is size-adjustable in at least one dimension.
In some embodiments, the back support includes at least one pivot arm configured to limit the pivotal range of motion of the back support. In other embodiments, the lumbar support includes at least one pivot block configured to interact with the at least one pivot arm.
In some embodiments, each of the seat support, the lumbar support, and the back support are formed of a rigid material, have a contoured shape ergonomically designed to correspond to the human body, and have a plurality of ventilation holes.
The invention and its particular features and advantages will become more apparent from the following detailed description considered with reference to the accompanying drawings.
The present invention is directed to a seating apparatus that is a postural support for the human body and responds to the natural motions of a user seated in an upright position. The seating apparatus includes a seat and back support that can be utilized together or separately in a variety of seating chassis, such as a wheelchair, automobile, stadium, auditorium, or airline seat.
The seating apparatus provides postural support through mechanisms that allow movement of a user's body independent of the seating chassis. As the user moves, her weight in the back and pelvic areas are redistributed. Preferably, the seat redistributes the user's body weight and pressure in the seat by permitting movement up-and-down and side-to-side. Preferably, the backrest redistributes the user's body weight by providing resilience for the user to lean rearwards and back up again, and permitting flexibility of the user's spinal column.
Referring now to the drawings, wherein like reference numerals designate corresponding structures throughout the views. The following examples are presented to further illustrate and explain the present invention and should not be taken as limiting in any regard.
The figures show exemplary embodiments of the present invention.
The seat 100 includes a seat frame 102. The seat frame 102 includes at least one receiving rod 101 having open ends to receive penetrating rods 103 on each end. In preferred embodiments, the seat frame 102 has a first receiving rod 101 positioned near the front of the seat 100 and a second receiving rod 101 positioned near the rear of the seat 100. Penetrating rods 103 have a first cross-sectional dimension and receiving rod 101 has a second cross-sectional dimension larger than the first cross-sectional dimension such that receiving rod 101 is configured for telescoping reception of the penetrating rods 103. Thus, a user can adjust the width of the seat frame 102 to fit various sized seating chassis. Preferably, receiving rod 101 and penetrating rods 103 have cylindrical cross-sections, but the invention contemplates other sufficiently shaped rods, such as rectangular or hexagonal cross-sections. Penetrating rod 103 has attachment member 108 for securing the seat 100 to a seating chassis. Preferably, attachment member 108 is a J-hook or a similar bracket that permits the seat 100 to be removably secured to a seating chassis 300, as shown in
In preferred embodiments, the seat frame 102 also includes at least one receiving rod 106 having an open end to receive penetrating rod 107. As seen in
In preferred embodiments, the seat frame components 101, 103, 106, and 107 use spring-biased detent mechanisms for preventing the frame components from inadvertent misalignment during adjustment of the seat frame 102. Preferably, receiving rods 101 and 106 include a plurality of detent holes 104 located near the open ends, and penetrating rods 103 and 107 include a spring-biased detent pin 105 located near the distal end. The detent holes 104 are configured to receive the detent pin 105 when the detent pin 105 is aligned with one of the plurality of detent holes 104. When the receiving rod 101/106 and penetrating rod 103/107 are adjusted relative to each other to align the detent pin 105 with a detent hole 104, the detent pin 105 springs into a locked position. A user can move the detent pin 105 back to the unlocked position by manually depressing the detent pin 105 against the spring bias, permitting the detent pint 105 to freely slide along an interior surface of receiving rod 101/106. In some embodiments, any other locking means known in the art are used to secure penetrating rods 103/107 to receiving rods 101/106. In other embodiments, no locking means are used.
The seat 100 also includes a seat support 111. Preferably the seat support 111 is formed of a rigid material, such as a molded composite material, has a contoured shape ergonomically designed to correspond to the human body, and has a plurality of ventilation holes 112. In some embodiments, the seat support 111 has a generally flat shape. In some embodiments, a seat pad constructed from a ventilated cushioning material is disposed on the seat support 111.
Preferably, the front end of seat support 111 is connected to the seat frame 102 through at least one fulcrum 116. In preferred embodiments, the front end of the seat support 111 is connected to the seat frame 102 through two fulcrums 116, as seen in the figures. Preferably, fulcrum 116 is a pivot bracket having a bore to receive an end of a pivot rod 109 of seat frame 102, as depicted in
Preferably, the rear end of seat support 111 is connected to the seat frame 102 through at least one spring assembly 130. In preferred embodiments, spring assembly 130 includes a mechanical spring 132 surrounding well-nuts 134. As depicted in
In preferred embodiments, the rear end of the seat support 111 is connected to the seat frame 102 through two spring assemblies 130, as seen in the figures. The relationship of the spring assemblies 130 to the fulcrums 116 determines the dynamic motion provided by the seat 100, such that the pivoting action is initiated across the transverse horizontal axis of the seat frame 102 and the seat support 111 moves bilaterally up, down, and side-to-side.
Preferably, the springs 132 are sized so as to normalize the seat support 111 in a position substantially parallel to the seat frame 102 when no force is applied to the seat 100. When force is applied to the seat support 111, the spring 132 compresses a distance 140, permitting the seat support 111 to pivot a corresponding angle 150, as shown in
In preferred embodiments, the seat support includes a plurality of fastening holes 114 for various placements of spring assemblies 130 along the length of the seat support 111. The various placements of the spring assemblies 130 affects the seat impact on a user, the distribution of the user's weight, and the activation of the user's pelvis and hip joints.
The backrest 200 includes a back frame 202. The back frame 202 includes at least one receiving rod or bar 201 having open ends to receive penetrating rods 203 on each end. In preferred embodiments, the back frame 202 has two parallel receiving rods/bars 201 stacked vertically, as shown in the figures. Penetrating rods 203 have a first cross-sectional dimension and receiving rod 201 has a second cross-sectional dimension larger than the first cross-sectional dimension such that receiving rod 201 is configured for telescoping reception of the penetrating rods 203. Thus, a user can adjust the width of the back frame 202 to fit various sized seating chassis. Preferably, receiving rod 201 and penetrating rods 203 have cylindrical cross-sections, but the invention contemplates other sufficiently shaped rods, such as rectangular or hexagonal cross-sections or other cross section shapes. In some embodiments, the penetrating rods 203 are secured to the receiving rod 201 by a spring-biased detent mechanism, as described above. In some embodiments, any other locking means known in the art are used to secure penetrating rods 203 to the receiving rod 201. In other embodiments, no locking means are used.
In preferred embodiments, penetrating rods 203 are connected to attachment brackets 206. Attachment brackets 206 have a plurality of laterally extending slots 208 through which bolts, or other mechanical fasteners, connect attachment members 204 to the attachment brackets 206. Preferably, the laterally extending slots 208 permit a user to adjust the depth of the back frame 202. In preferred embodiments, attachment member 204 is a clamp or a similar mechanism that permits the backrest 200 to be removeably secured to a seating chassis 300, as shown in
The backrest 200 also includes a lumbar support 210. Preferably, the lumbar support 210 is secured to the back frame 202 by loop clamps 212 that contour to the shape of the receiving rods 201, as depicted in
The backrest 200 further includes a back support 220 having a back support surface 222. Preferably the back support surface 222 is formed of a rigid material, such as a molded composite material, has a contoured shape ergonomically designed to correspond to the human body, and has a plurality of ventilation holes 224. In some embodiments, the back support surface 222 has a generally flat shape. In some embodiments, a back pad constructed from a ventilated cushioning material is disposed on the back support surface 222.
Preferably, the back support 220 is connected to the lumbar support 210 through at least one hinge 230. In preferred embodiments, the back support 220 is connected to the lumbar support 210 through two hinges 230, as seen in
The backrest 200 also includes at least one resilient pivotal member 240 positioned along adjacent surfaces of the lumbar support 210 and the back support 220 such that the back support 220 is capable of resilient pivoting about the transverse horizontal axis of the back frame 202. In some embodiments, the backrest 200 includes two resilient pivotal members 240. In preferred embodiments, the resilient pivotal members 240 are leaf springs, as shown in
When force is applied to the back support surface 222, the back support 220 pivots an angle 250 from the normal vertical position, as depicted in
In some embodiments, the back support 220 also includes at least one pivot arm 226. Preferably, pivot arm 226 is generally located below the hinge 230 and is angled away from the lumbar support 210, as shown in
In preferred embodiments, the lumbar support also includes at least one pivot block 216. Preferably, the pivot block 216 is positioned such that it interacts with the pivot arm 226 when the back support 220 pivots the maximum pivot angle 250, as depicted in
Although the invention has been described with reference to a particular arrangement of parts, features, and the like, these are not intended to exhaust all possible arrangements or features, and indeed many other modifications are variations will be ascertainable to those of skill in the art.
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