The present invention relates to a chair that promotes active engagement of selected muscles of the user.
Various aspects of the invention are described in the claims section which is incorporated in this Summary section by reference.
In one aspect, the invention provides an upper chair adapted to be supported by a lower chair, the upper chair comprising: a seat adapted to cradle the ischial tuberosities of a user, wherein a horizontal upper chair pivot axis is the sole pivotal interconnection between the upper chair and lower chair.
In some embodiments, the upper chair includes a back and the horizontal upper chair pivot axis is above the seat and forward of the back. In some embodiments, the invention further comprises a back extending up with respect to the seat, at least a portion of the back having a 21° range of pivotable motion with respect to the seat. In some embodiments, the invention further comprises a back extending up with respect to the seat, the upper chair pivot axis being forward of the back. In some embodiments, the seat comprises a pelvic nest for cradling ischial tuberosities of a user, a thigh pad engaging the user's posterior thighs forward of the pelvic nest, and a thigh relief interconnecting the pelvic nest and the thigh pad for permitting compliant deflection of the thigh pad with respect to the pelvic nest, the upper chair further comprising: a back pad assembly extending up with respect to the seat and including upper and lower portions, the lower portion of the back pad assembly supported by the lower back support, the lower back support being pivotable to move the lower portion of the back pad assembly respect to the thoracic support and the pelvic nest. In some embodiments, the thigh pad pivots downward with respect to the pelvic nest no more than 45°. In some embodiments, the pelvic nest positions the user's ischial tuberosities below the upper chair pivot axis. In some embodiments, the thigh relief distributes and reduces pressures on portions of the user's posterior thighs positioned over the thigh relief. In some embodiments, an ingress condition of the upper chair comprises the thigh pad being pivoted downward with respect to the pelvic nest and the lower back support and lower portion of the back pad assembly being pivoted rearward with respect to the pelvic nest; and an engaged condition of the chair comprises the thigh pad being pivoted upward with respect to the pelvic nest and the lower back support and lower portion of the back pad assembly being pivoted forward with respect to the pelvic nest. In some embodiments, when the chair is in the engaged condition the thigh pad applies dynamic pressure on the user's posterior thighs to activate muscles in the user's thighs and thereby assist the user to naturally leverage and balance a torso, spine, and pelvis of the user in a neutral posture. In some embodiments, when the chair is in the engaged condition the lower portion of the back pad assembly applies dynamic pressure on the user's sacrum to resist posterior rotation of the user's pelvis. In some embodiments, the invention further comprises a thigh return spring biasing the thigh pad into the ingress position and a sacral return spring biasing the lower back support into the ingress position. In some embodiments, the lower portion of the back pad assembly is pivotably and slidably mounted to the lower back support about a sliding lower back pivot axis; and pivotal movement of the lower back support member applies a linear force on the lower portion of the back pad assembly perpendicular to the sacral sliding pivot axis to move the lower portion of the back pad assembly between the ingress position and engaged position. In some embodiments, the sacral sliding pivot axis is horizontal and coincident to a center of pressure applied to the lower portion of the back pad assembly by the user such that the lower portion of the back pad assembly is free to pivot about the sacral sliding pivot axis to orient the lower portion of the back pad assembly to an angle of the user's sacrum. In some embodiments, the invention further comprises a pulley mounted under the pelvic nest, a nesting cable interconnected at opposite ends to the thigh pad and the lower back support, the nesting cable extending over the pulley such that downward force on the pelvic nest arising from the user sitting in the pelvic nest generates tension in the nesting cable to pivot each of the thigh pad and the lower back support into the engaged condition. In some embodiments: the lower back support pivots about a posterior pivot axis below and rearward of the upper chair pivot axis; the lower back support includes a lower back cam surface through which the posterior pivot axis extends; a first end of the nesting cable is connected to the lower back support; and the nesting cable engages the lower back cam surface such that tension in the nesting cable generates a moment on the lower back support about the posterior pivot axis to move the lower portion of the back pad assembly into the engaged position. In some embodiments, the lower back support has a 21° range of pivotable motion with respect to the posterior pivot axis. In some embodiments, the upper chair includes a body support frame pivotably mounted to the lower chair about the upper chair pivot axis, the body support frame extending below the seat and behind the back, the seat being supported by the body support frame, the upper portion of the back pivoting with respect to the body support frame about the thoracic pivot axis. In some embodiments, the invention further comprises a thigh support pivotably interconnected to the body support frame about a horizontal hip pivot axis that is below and forward of the upper chair pivot axis, the thigh pad being interconnected with the thigh support via a thigh pad sliding pivot axis under the thigh pad to enable relative rotation and translation between the thigh pad and thigh support. In some embodiments: the thigh support includes a hip cam surface that is eccentrically positioned on the hip pivot axis; a second end of the nesting cable connects to the thigh support; and the nesting cable engages the hip cam surface such that tension in the nesting cable generates a moment on the thigh support about the hip pivot axis to move the thigh pad into the engaged position. In some embodiments, the invention further comprises at least one travel stop for limiting the total rotation of the of the body support frame with respect to the yoke about the upper chair pivot axis to a total range of 12°.
In another aspect, the invention provides a chair comprising: a lower chair including a tilt-swivel mechanism defining a vertical swivel axis, a yoke, and a column extending between the tilt-swivel mechanism and the yoke; and an upper chair pivotably mounted to the yoke about a horizontal upper chair pivot axis, the upper chair including a seat adapted to cradle the ischial tuberosities of a user.
In some embodiments, the tilt-swivel mechanism includes a four-bar linkage rotatable about the swivel axis, the four-bar linkage including a coupler member that moves about a coupler curve; and a bottom end of the column is supported by the coupler member for movement with the coupler member about the coupler curve and rotation about the swivel axis. In some embodiments, the column defines a longitudinal axis angled with respect to the swivel axis and intersecting the swivel axis. In some embodiments, the column is locked with respect to the tilt-swivel mechanism against rotation about the longitudinal axis. In some embodiments, the tilt-swivel mechanism provides independent swivel and tilting actions for the column. In some embodiments, a tilting range of motion of the column on the tilt-swivel mechanism is limited to between 80-90° with respect to horizontal. In some embodiments, a tilting range of motion of the column on the tilt-swivel mechanism is limited to between 82-87° with respect to horizontal. In some embodiments, the tilt-swivel mechanism permits 360° of column swivel about the swivel axis. In some embodiments, the column is a height-adjustable column permitting adjustment of a distance between the yoke and the tilt-swivel mechanism. In some embodiments, the height-adjustable column accommodates users between the 5th and 95th percentile of sizes. In some embodiments, the height-adjustable column enables the user to sit in multiple tilted positions with a thigh-to-torso angle in the range of 90° to 130°. In some embodiments, the invention further comprises a dampener between the column and tilt-swivel mechanism for controlling a rate of tilting motion of the column on the tilt-swivel mechanism and a dampener between the yoke and upper chair for controlling a rate of tilting motion of the upper chair with respect to the yoke about the upper pivot axis. In some embodiments, the lower chair further comprises a base onto which the tilt-swivel mechanism is mounted and casters supporting the base above a floor, the casters enabling rolling motion of the chair on the floor. In some embodiments, a center of mass of the user is maintained over the base through a full range of motion afforded by the tilt-swivel mechanism. In some embodiments, the invention further comprises a biasing mechanism for moving the column into an at-rest position when the seat is not occupied by a user. In some embodiments, the horizontal upper chair pivot axis is above the seat. In some embodiments, the upper chair pivot axis is the sole pivotal interconnection between the upper chair and lower chair. In some embodiments, a pivoting motion of the upper chair about the upper chair pivot axis is independent of tilt and swivel motions of the support column on the tilt-swivel mechanism. In some embodiments, the upper chair further comprises a back extending up with respect to the seat, at least a portion of the back having a 21° range of pivotable motion with respect to the seat. In some embodiments, the upper chair further comprises a back extending up with respect to the seat, the upper chair pivot axis being forward of the back. In some embodiments: the seat comprises a pelvic nest for cradling the ischial tuberosities of the user, a thigh pad engaging the user's posterior thighs forward of the pelvic nest, and a thigh relief interconnecting the pelvic nest and the thigh pad for permitting compliant deflection of the thigh pad with respect to the pelvic nest; and the upper chair further comprises a back extending up with respect to the seat and including an upper portion and a lower portion, the upper and lower portions being pivotable with respect to each other. In some embodiments, the pelvic nest positions the user's ischial tuberosities below the upper chair pivot axis. In some embodiments, the upper chair pivots about the upper chair pivot axis to maintain the pelvic nest in a consistent attitude with respect to the user's ischial tuberosities through a range of tilting motion of the tilt-swivel mechanism, such that the user's ischial tuberosities are maintained in the pelvic nest through the range of motion. In some embodiments, the thigh pad has a 35° range of pivotable motion with respect to the pelvic nest. In some embodiments, the thigh relief distributes and reduces pressures on portions of the user's posterior thighs positioned over the thigh relief. In some embodiments, an ingress condition of the chair comprises the thigh pad being pivoted downward with respect to the pelvic nest and the back being pivoted rearward with respect to the pelvic nest; and an engaged condition of the chair comprises the thigh pad being pivoted upward with respect to the pelvic nest and the lower portion of the back being pivoted forward with respect to the pelvic nest. In some embodiments, when the chair is in the engaged condition the thigh pad applies dynamic pressure on the user's posterior thighs to activate muscles in the user's thighs and thereby assist the user to naturally leverage and balance a torso, spine, and pelvis of the user in a neutral posture. In some embodiments, when the chair is in the engaged condition the lower portion of the back engages the user's lumbar spine and sacrum to resist posterior rotation of the user's pelvis. In some embodiments, the invention further comprises a thigh return spring biasing the thigh pad into the ingress position and a sacral return spring biasing the lower back support into the ingress position. In some embodiments, the lower portion of the back is pivotably and slidably mounted to the lower back support about a sliding lower back pivot axis; and pivotal movement of the lower back support member applies a linear force on the lower portion of the back perpendicular to the sacral sliding pivot axis to move the lower portion of the back between the ingress position and engaged position. In some embodiments, the sacral sliding pivot axis is horizontal and coincident to a center of pressure applied to the lower portion of the back by the user such that the lower portion of the back is free to pivot about the sacral sliding pivot axis to orient the lower portion of the back to an angle of the user's lumbar spine and sacrum. In some embodiments, the invention further comprises a pulley mounted under the pelvic nest, a nesting cable interconnected at opposite ends to the thigh pad and the lower back support, the nesting cable extending over the pulley such that downward force on the pelvic nest arising from the user sitting in the pelvic nest generates tension in the nesting cable to pivot each of the thigh pad and the lower back support into the engaged condition. In some embodiments: the lower back support pivots about a posterior pivot axis below and rearward of the upper chair pivot axis; the lower back support includes a lower back cam surface through which the posterior pivot axis extends; a first end of the nesting cable is connected to the lower back support; and the nesting cable engages the lower back cam surface such that tension in the nesting cable generates a moment on the lower back support about the posterior pivot axis to move the lower portion of the back into the engaged position. In some embodiments, the lower back support has a 21° range of pivotable motion with respect to the posterior pivot axis. In some embodiments, the upper chair includes a body support frame pivotably mounted to the yoke about the upper chair pivot axis, the body support frame extending below the seat and behind the back, the seat being supported by the body support frame, the upper portion of the back pivoting with respect to the body support frame about the thoracic pivot axis. In some embodiments, the invention further comprises a thigh support pivotably interconnected to the body support frame about a horizontal hip pivot axis that is below and forward of the upper chair pivot axis, the thigh pad being interconnected with the thigh support via a thigh pad sliding pivot axis under the thigh pad to enable relative rotation and translation between the thigh pad and thigh support. In some embodiments: the thigh support includes a hip cam surface that is eccentrically positioned on the hip pivot axis; a second end of the nesting cable connects to the thigh support; and the nesting cable engages the hip cam surface such that tension in the nesting cable generates a moment on the thigh support about the hip pivot axis to move the thigh pad into the engaged position. In some embodiments, the invention further comprises at least one travel stop for limiting the total rotation of the of the body support frame with respect to the yoke about the upper chair pivot axis to a total range of 12°.
In another aspect, the invention provides a lower chair for supporting an upper chair on which a user sits, the lower chair comprising: a base; a swivel mechanism supported by the base, defining a vertical swivel axis; a four-bar assembly mounted to the swivel mechanism for rotation about the swivel axis, the four-bar assembly including a coupler link that moves about a coupler curve; a column having a lower end affixed to the coupler link for movement of the lower end along the coupler curve, the column defining a column axis and adapted to support the upper chair.
In some embodiments, the invention further comprises a yoke mounted to an upper end of the column opposite the lower end, the yoke adapted for interconnection to the upper chair for relatively pivotal movement of the upper chair with respect to the yoke about a horizontal upper chair pivot axis. In some embodiments, the upper chair pivot axis is the sole pivotal interconnection between the upper chair and lower chair. In some embodiments, the column defines a longitudinal axis angled with respect to the swivel axis and intersecting the swivel axis. In some embodiments, the lower end of the column is affixed to the coupler link to prevent rotation of the column about the longitudinal axis with respect to the coupler link. In some embodiments, the a range of motion of the four-bar linkage is limited by stops to limit a range of motion of the coupler link along the coupler curve. In some embodiments, motion of the lower end of the column along the coupler curve effects tilting of the column within a tilting range of motion limited to between 80-90° with respect to horizontal. In some embodiments, motion of the lower end of the column along the coupler curve effects tilting of the column within a tilting range of motion limited to between 82-87° with respect to horizontal. In some embodiments, rotation of the tilt mechanism on the swivel mechanism permits 360° of column swivel about the swivel axis. In some embodiments, the invention further comprises a dampener in the four-bar linkage for controlling a rate of movement of the column along the coupler curve. In some embodiments, the invention further comprises casters supporting the base above a floor, the casters enabling rolling motion of the lower chair on the floor. In some embodiments, the invention further comprises a biasing mechanism for moving the four-bar linkage into an at-rest position the upper chair is not occupied.
Other aspects of the invention will become apparent by consideration of the detailed description and accompanying drawings.
Before any embodiments of the invention are explained in detail, it is to be understood that the invention is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawings. The invention is capable of other embodiments and of being practiced or of being carried out in various ways.
The present invention relates to a chair having multiple pivot axes for accommodating the natural movements of the user's body, while maintaining the user in an active, engaged, “ready” posture. To avoid crowding the drawings with reference numbers for different ends, sides, etc. of parts of the chair, it will be presumed that one of ordinary skill will read this disclosure with the ordinary meaning of directional and positional terms in mind. Throughout this disclosure, for example, the terms “left,” “right,” “rear,” and “front” are used from the perspective of an occupant or user seated in the chair. Terms such as “top” and “bottom” are used with respect to the intended ordinary condition of the chair. The term “above” means that one component is positioned higher than another with necessarily being in the same vertical plane. The term “vertically above” means that one component is higher than another thing and in the same vertical plane. “Below” means a component is lower than another component, whereas “vertically below” means that the component is lower and also within the same vertical plane as the other component.
For parts and regions of the user's body, reference is made to
Lower Chair
With continued reference to
The casters 130 provide rolling motion in the horizontal plane of the floor. Referring to
The tilt-swivel mechanism 160 is illustrated in
Referring again to
Referring now to
Referring back to
The coupler member 320 also includes a clearance space 320d (
The upper pivot crossbar 330 is mounted at opposite ends to the vertical sides of the ground frame 310. The lower pivot cross bar 335 is mounted at opposite ends to the front end of the coupler member 320. With reference to
The configuration results in the coupler member 320 hanging down inside (i.e., nested within) the ground frame 310 and swinging or gliding with respect to the ground frame 310. The return springs 360 are illustrated as torsion springs, each include a first end bearing against the coupler member 320 and a second end bearing against one of the front links 350. The second end of the return springs 360 may be received in a notch in the side of the front links 350. For convenience of manufacture and assembly, the front links 350 may be made with notches on both side so that the same part can be used on the right and left sides of the mechanism 160. The return springs 360 bias the tilt mechanism 210 into the full-forward position or ingress position, which will be described below. As seen in
It will be appreciated that the tilt mechanism 210 is a four-bar assembly or linkage. A four-bar assembly includes a ground link, a coupler link (sometimes called a floater link), and two additional links (often called an input link and an output link) that are pivotably connected to each of the ground link and coupler link. In the tilt mechanism 210, the ground frame 310 (or each of its left and right vertical sides) is analogous to the ground link, the coupler member 320 (or each of its left and right sides) is analogous to the coupler link, and the rear links 340 and front links 350 are analogous to the input and output links. It is not important for the purposes of the present invention whether the rear links 340 or front links 350 are considered analogous to the respective “input link” and “output link” of a model four-bar assembly. As noted above, the front and rear links 340, 350 are pivotably interconnected to the ground frame 310 and coupler member 320 about four parallel (horizontal) axes 340a, 340b, 350a, 350b, one axis at each end of the links 340, 350.
The constrained motion of the coupler member 320 with respect to the ground frame 310 will now be explained with reference to
The constrained motion of the tilt mechanism 210 causes the coupler member 320 (and thus the height-adjustable column 150, yoke 170, and upper chair 120) to describe a coupler curve. The height-adjustable column 150 therefore moves about the coupler curve to change the angle of the longitudinal axis 150a with respect to vertical. The longitudinal axis 150a is disposed at an angle α with respect to the vertical swivel axis 230a and intersects the swivel axis 230a. The swivel axis 230a is offset from the longitudinal axis 150a. The swivel mechanism 220 permits the height-adjustable column 150 to orbit a full 360° about the swivel axis 230a.
In the illustrated embodiment and in other preferred embodiments, the longitudinal axis 150a is prevented from being vertical (i.e., the setup is such that the angle of tilt α is prevented from being 0°). Preventing a vertical longitudinal axis 150a causes the user to always have an engaged core and activates other muscle groups in addition to bearing a significant portion of the user's weight on the user's feet, as will be described below in the user interaction section of this disclosure.
Referring now to
As will be explained in more detail below, the upper chair 120 is mounted to the free ends of the uprights 170b for pivoting about a horizontal upper chair pivot axis 400. The upper chair pivot axis 400 is the sole pivotal interconnection between the upper chair 120 and the lower chair 110. Because the arm rests 390 are mounted to the uprights 170b, they remain stationary with respect to the yoke 170 as the upper chair 120 pivots about the upper chair pivot axis 400. The yoke 170 also has a downwardly-open taper joint 170d at the bottom center of the base 170a. The taper joint 170d receives the top end of the height-adjustable column 150. The uprights 170b are equally spaced from taper joint 170d.
It will be appreciated in view of the above description, in combination with the following description of the upper chair 120, that the tilt-swivel mechanism 160 provides tilting motion of the lower chair 110 in a prescribed fore-aft coupler motion that maintains the seated user on a relatively level horizontal plane without dumping the user out of the upper chair 120.
This offset further allows the height-adjustable column 150 to tilt toward and away from the central swivel axis 230a from a position off-center with respect to the base 140 to maintain the user's center of mass over the base 140 and casters 130 through the full range of tilting and swiveling motion and through the full range of the height-adjustable column 150. Consequently, the user can move in any swivel position and tilting position without tipping over or the chair sliding away from the user.
The height-adjustable column 150 provides a range of seat heights that accommodates the 5th to 95th percentile user sizes in both active and offloaded sitting postures. The seated height range is controlled when the user activates the height-adjustable column 150 via a control lever. The adjustable seat height range allows a user to sit in multiple tilted and swiveled positions with a thigh-to-torso angle γ (
It should be appreciated that in other configurations or embodiments of the invention, the tilt mechanism 210 and/or the swivel mechanism 220 can be removed from the base 140. For example, the tilt mechanism 210 could be removed such that the base of the height-adjustable column 150 is mounted directly to the swivel mechanism 220. Likewise, the swivel mechanism 220 could be removed such that the tilt mechanism 210 is directly mounted to the base 140. Last, both the tilt mechanism 210 and swivel mechanism 220 could both be removed such that the base of the height-adjustable column 150 is mounted directly to the base 140 of the chair 100. In embodiments where the tilt mechanism 210 is removed, the height-adjustable column 150 may be set at fixed angle of tilt α within the ranges described in this disclosure. In other embodiments, a locking mechanism may be added to the tilt mechanism 210 to lock the tilt mechanism 210 at a desired angle of tilt α within the ranges described in this disclosure. The locking mechanism can be unlocked to adjust the angle of tilt α, and then reengaged to lock the tilt mechanism 210 at a new angle of tilt α. Alternatively, the locking mechanism may remain unlocked to permit free tilting if desired by the user.
Upper Chair
Referring to
The body support frame 510 includes a generally horizontal seat portion 510a and a generally vertical back portion 510b. The horizontal seat portion 510a extends along the left and right sides of the upper chair 120 and the vertical back portion 510b is centered and at the rear of the upper chair 120. The vertical back portion 510b includes an upper pivot mount 510c which forms part of an upper pivot assembly that defines a thoracic pivot axis 535. The body support frame 510 is integrally formed as a single unit and is generally rigid. The body support frame 510 supports the user and controls the dynamic functions of the upper chair 120.
A SI pivot resistance applies a biasing moment to the body support frame 510 to control the rotation force about the upper chair pivot axis 400. The SI pivot damping controls the rotation rate about the upper chair pivot axis 400 and increases the user's control of motion and position. The body support frame 510 travel stops limit the total rotation of the of the body support frame 510 relative the yoke 170 to a total range of 12°.
Referring now to
With reference to
The seat pan 540 includes a pelvic nest 540a and a pair of rearwardly-extending seat pan arms 540b. The pelvic nest 540a is a relatively horizontal surface with specific shape, contour, location and compliance that positions and orients the seated user's inferior pelvis in the rear portion of the upper chair 120 without sliding out during ingress and chair motions. The pelvic nest 540a may also be referred to as a “seat nest” or a “seat pocket.” The seat pan arms 540b are pivotably mounted to the body support frame 510 by way of a pivot pin 563 on each side. The pivot pins 563 define the posterior pivot axis 533. The posterior pivot axis 533 is at the rear of the seat pan 540 and the seat pan 540 pivots in front of the posterior pivot axis 533.
The bottom layer 550 and top layer 555 may be referred to as the cushion assembly 550, 555. The front part of the cushion assembly 550, 555 may be referred to as a thigh pad. The cushion assembly 500, 555 cooperates with the seat pan 540 to distribute pressure, with focal points at the user's ischial tuberosities. The cushion assembly 550, 555 includes support surfaces and cushioning materials adjacent to the focal points to distribute pressure on the user's body. Support surfaces and cushioning materials have interdependent flex, varying stiffness, specific shapes and orientations. Additionally, the cushion assembly 550, 555 includes rigid regions that support a large majority of a user's weight. The posterior pivot axis 533, about which the pelvic nest rotates, is positioned below the user's spine and rearward of the users ischial tuberosities.
The top layer 555 may be a foam cushion or a webbing depending on the desired application. The top layer 555 is secured to the bottom layer 550 to form the inseparable, unified cushion assembly 550, 555.
The bottom layer 550 includes a rear portion 550a that is fastened to the seat pan 540, a thigh relief portion 550b, and a thigh relief track 550c (
The thigh relief pivot axis 531 is a living hinge or flexible section provided by the combination of the resilient material of the bottom layer 550 and the arrangement of slits and other relief features in the thigh relief portion 550b. The thigh relief pivot axis 531 is forward of the hip pivot axis 532. Although illustrated as a line in the drawings, the thigh relief pivot axis 531 may in the commercial embodiment be a smooth curve of a section of the bottom layer 550. Referring to
Referring now to
The thigh support 560 includes an integral thigh slide connector 560a at the center of its base portion. The integral thigh slide connector 560a comprises a horizontal slide pin having free ends. The thigh slide connector 560a is received in the thigh relief track 550c on the underside of the bottom layer 550, with the free ends of the integral slide pin in the undercuts of the thigh relief track 550c. The thigh slide connector 560a is therefore captured in the thigh relief track 550c such that the thigh slide connector 560a can only slide linearly along the thigh relief track 550c (i.e., forward and rearward). The thigh slide connector 560a slides along the thigh relief track 550c while transferring forces perpendicular to the slide pin between the thigh support 560 and the bottom layer 550, to cause pivoting of the thigh relief portion 550b about the thigh pivot axis 531. Movement of the thigh slide connector 560a along the thigh relief track 550c avoids the transfer of force in forward and rearward directions (i.e., along the extent of the thigh relief track 550c) between the thigh slide connector 560a and the cushion assembly 550, 555. The thigh support 560 also has a hip cam 560b that is eccentric with the hip axis 532. As will be described in more detail below, the hip cam 560b is used by the nest actuator assembly to actuate the thigh support 560.
Referring to
With reference to
The lower back support 570 includes a hub 570a and an arm 570b. The hub 570a is at the bottom or base of the lower back support 570. The hub 570a is pivotably mounted to the body support frame 510 by way of the pivot pins 563 which extend through the arms 540b of the seat pan 540 and define the posterior pivot axis 533. The posterior pivot axis 533 is through the hub 570a at the bottom of the lower back support 570 and the arm 570b pivots above the posterior pivot axis 533. Additionally, the lower back support 570 pivots coaxially with the seat pan 540 about the posterior pivot axis 533 with respect to the body support frame 510. The arm 570b includes a lower back slide connector 570c pivotably mounted at the top end of the arm 570a. The lower back slide connector 570c includes wings, the significance of which will be explained below. The lower back return spring 590 is a torsion spring with two coils on opposite sides of the hub 570a, two free ends that bear against the body support frame 510, and a central portion that extends across the lower part of the arm 570b above the hub 570a. The lower back return spring 590 biases the lower back support 570 to the ingress position in which the lower back support 570 is pivoted rearwardly to open the pelvic nest 540a when the user enters and exits the chair 100.
As will be discussed in more detail below, pressure applied from the lower back support 570 on the user's sacrum prevents posterior rotation of the pelvis and spine kyphosis of a seated user. The lower back support 570 rotates fore/aft to accommodate variation in user's pelvic size and pelvis position, (i.e. the variation of the longitudinal distance from the ischial tuberosity to the sacral crest). The lower back support 570 has a forward stop position and a rearward stop position. The rotation range from the forward stop position to the rearward stop position is approximately 21 degrees (21°).
With continued reference to
The case 584 includes a forward facing portion 584f against which the seat user's back rests and a rear facing portion 584r that includes a lower back cavity 584a and a window 584b. In the illustrated embodiment, the case 584 is shown in two pieces, with the forward facing portion 584f in front of the scaffold 582 and the rear facing portion 584r behind the scaffold 582. Alternatively, the case 584 can be overmolded onto the scaffold 582. In any event, the scaffold 582 is inside or embedded in the case 584. The illustrated embodiment is not limiting. The front portion 584f could take the form of a web or mesh material that is desirable for contact with the user's back. The rear portion 584r could be more rigid or solid than the front portion 584f to be most suitable for the functionality of the lower back cavity 584a, described below. Because the case 584 is mounted to the scaffold 582 such that the overall back pad assembly 580 functions as an integrated unit, the portions of the overall back pad assembly 580 corresponding to the lower, upper, and relief portions 582a, 582b, 582c of the scaffold 582 can be referred to as the respective lower, upper, and relief portions of the overall back pad assembly 580.
The back pad assembly 580 also includes a lower back track 580a received in the lower back cavity 584a and an upper pivot mount 580b mounted to the upper bosses 582d and extending through the window 584b. Both the lower back track 580a and the upper pivot mount 580b are on the rear-facing side of the case 584. The lower back track 580a includes side channels on opposite sides of a central slot. The side channels receive the wings of the lower back slide connector 570c. The side channels capture the wings of the lower back slide connector 570 to permit only vertical movement of the lower back slide connector 570c in the lower back track 584a. As noted above, however, the lower back slide connector 570c is pivotably connected to the top of the arm 570b of the lower back support 570.
As a result, the lower back support 570 and the lower back slide connector 570c pivot with respect to each other about the lower back pivot axis 534, and the lower back pivot axis 534 is vertically-adjustable. The lower back pivot axis 534 is a horizontal axis coincident to the center of pressure applied to the back pad assembly 580 by the user. The lower back pivot axis 534 permits pivotal movement of the lower portion 582a of the scaffold 582 with respect to the lower back support 570.
The upper pivot mount 580b includes an integral hinge pin in the illustrated embodiment. The upper pivot mount 580b cooperates with (i.e., is received by, in the illustrated embodiment) the upper pivot mount 510c of the back portion 510b of the body support frame 510. The upper pivot mount 580b of the back pad assembly 580 and the upper pivot mount 510c of the back portion 510b together form an upper pivot assembly that defines the thoracic pivot axis 535. The back pad assembly 580 (and more specifically the upper portion 582b) pivots about the thoracic pivot axis 535 to accommodate the angle of the user's thoracic region. The back pad assembly 580 is pivotably connected to the body support frame 510 at the horizontal thoracic pivot axis 535 for pivoting motion about the thoracic pivot axis 535. The upper pivot assembly 510c, 580b constrains the back pad assembly 580 against vertical linear movement with respect to the body support frame 510.
The relief portion 582c provides sufficient compliance in the back pad assembly 580 to permit the lower and upper portions 582a, 582b to pivot with respect to each other as the lower portion 582a pivots on the lower back pivot axis 534 and the upper portion 582b pivots on the thoracic pivot axis 535. This pivoting is about a mid-back pivot axis 582f in the relief portion 582c, and provides yet another degree of freedom for the upper chair 120. The mid-back pivot axis 582f is a horizontal pivot axis through the relief portion 582c.
Turning to
The pulley 620 is mounted to front (on one side) of the seat pan 540 to redirect the nesting cable 610 from being aligned with the hip cam 560b toward alignment with the lower back cam 560b. With additional reference to
A sheath 650 surrounds the nesting cable 610 under the seat pan 540. With reference to
As illustrated in
As seen in
This tension, acting through the hip cam surface 560b and lower back cam 640, simultaneously applies moments to the thigh support 560 (about the hip pivot axis 532) and lower back support 570 (about the posterior pivot axis 533). The moments pivot the thigh support 560 up against the underside of the user's thighs and the lower back support 570 forward against the user's lower back (i.e., sacrum and lumbar region). The tension also opposes rotation of the pelvic nest 540 under the user's weight. The overall result of the action of the nest actuator assembly 530 is to apply opposing pressures on the underside of the user's thighs and on the user's lower back as the user's posterior is lowered on the seat pan 540. The user's weight is the actuating force on the nest actuator assembly. The hip cam surface 560b and lower back cam 640 and moment arms (e.g., the thigh support 560 and the lower back support 570) are design to generate the opposing pressures in desirable proportions to the user's weight. The respective upward pivoting of the thigh support 560 and the forward pivoting of the lower back support 570 may be referred to as the “engaged position” for those components.
Broadly speaking, the thigh support 560 and the lower back support 570 can be referred to as respective first and second components defining between them a receiving space for a user's pelvis, and the nesting actuator assembly 530 may be referred to as an actuator that moves the first and second components in directions that change the shape of the receiving space. The actuator can be said to cause the first component to engage the user's thighs and the second component to engage the user's lower back with a clamping force related to the weight of the user.
Alternative Upper Seat
The seat frame 740 includes a base portion 740a, a pair of seat frame arms 740b extending rearward from the base portion 740a, and a pair of seat pan arms 740c extending forward from the base portion 740a. The seat frame 740 is relatively rigid. Suitable materials for construction of the seat frame 740 include but are not limited to aluminum and glass-filled nylon. The seat frame arms 740b are pivotably mounted to the body support frame 510 by way of the pivot pins 563. The seat pan arms 740c extend along opposite sides of the seat assembly 720. Each seat pan arm 740c includes one of the above-described pulleys 620 at its free forward end. As described above, the nesting cables 610 are routed through the pulleys 620 to the hip cams 560b on the horizontal seat portions 510a of the body support frame 510.
The beam 743 spans the space between the seat pan arms 740c a little closer to the free forward ends of the seat pan arms 740c than to the base portion 740a. The illustrated beam 743 is a composite spring. The beam 743 is wider than it is thick such that it has a relatively high moment of inertia about a vertical axis but can be bowed downward in the center under the weight of a seat user. The beam 743 is mounted at opposite ends to the seat pan arms 740c by way of mounting blocks 760. The mounting blocks 760 prevent significant movement of ends of the beam 743 transverse to its longitudinal extent, but permit the ends of the beam 743 to slide a small amount toward each other as the beam 743 is deflected downward in the middle. The mounting blocks 760 also permit the ends of the beam to slide away from each other while still being captured in the mounting blocks 760 as the beam 743 returns to its flat condition when the user's weight is removed. For example, in one construction there may be one millimeter (1 mm) of total play between the ends of the undeflected beam 743 and the mounting blocks 760 (i.e., the beam 743 may be 1 mm shorter than the width between contact points on the opposite seat pan arms 740c). The beam 743 may deflect, for example, one inch (1″) downward at the center under the user's weight. A spring block 770 is affixed to the center of the beam 743. A plurality of thigh return springs 565 (as described above and illustrated in
The seat pan 745 includes a seat pan frame 745a and a pelvic nest 745b. Although illustrated as separate components, seat pan frame 745a and pelvic nest 745b are preferably molded from plastic as a single piece. The seat pan frame 745a defines a continuous rim around the seat pan 745. The seat pan frame 745a angles downward as it extends toward the center of the seat pan 745 to create a concave, dished or cupped border of the seat pan 745. Flexible side regions 745c of the seat pan frame 745a are highly flexible to permit the front portion of the seat pan frame 745a to pivot up and down with the thigh support 560 relative to the rear portion of the seat pan frame 745a. In the illustrated embodiment, the flexible side regions 745c may also be referred to as thin side regions. The front portions of the seat pan 745 frame 745a, seat pad 750, and padded top layer 755 (i.e., those portions forward of the flexible side regions 745c) may be referred to as a thigh pad in this embodiment.
A slit 745d is formed in a front portion of the pelvic nest 745b to separate the front edge of the pelvic nest 745b from a deflectable portion 745e. The slit 745d in combination with the thin, flexible side regions 745c provide a thigh relief portion interconnecting the pelvic nest 745b and the thigh pad for permitting compliant deflection of the thigh pad with respect to the pelvic nest 745b. The slit 745d gives the deflectable portion 745e the freedom to resiliently deflect down with respect to the seat pan frame 745a under the weight of a seated user. The resilient material of the pelvic nest 745b biases the deflectable portion 745e back to its at-rest condition when the user's weight is removed. As a result, the deflectable portion 745e of the pelvic nest 745a applies a generally upward biasing force against the bottom of a seated user.
The deflectable portion 745e includes IT panels 745f that receive the ischial tuberosities of the seated user. The IT panels 745f are angled slightly toward each other such that the reactive forces F (
The seat pad 750 is a plastic layer that overlays the pelvic nest 745a and spans the slit 745d to the front portion of the seat pan frame 745a. The seat pad 750 is made of a plastic that is softer than the plastic of the seat pan 745. For example and without excluding other suitable materials, the seat pad 750 may be constructed of a thermoplastic elastomer (TPE) such as thermoplastic polyurethane (TPU). The seat pad 750 is rather thin but nonetheless has the effect of softening edges of the seat pan 745 and providing more conformance to the bottom of a user seated in the chair than the stiffer plastic from which the seat pan 745 is constructed. The padded top layer 755 is much the same as the top layer 555 described above. It may be a foam cushion or a webbing depending on the desired application.
The positioning of the beam 743 and the shape of the seat pan 745 steer the user's ischial tuberosities to the specific, desired position on the IT panels 745e. Because of its cupped shape, seat pan 745 only contacts the beam 743 in the middle of the beam, mostly on top of the spring block 770. The IT panels 745e are positioned rearward of the beam 743. The beam 743 and resilient seat pan 745 act as stacked springs to support the user through the ischial tuberosities. The ischial tuberosities never bottom out against anything but are instead always suspended on the springy support of the seat pan 745.
Referring to
User Interaction
When the user activates the tilting motion (at the base), they can move fore/aft with very little effort and with controlled balance. This motion is activated and controlled by the forces of the feet applied to the floor. These forces on the feet also activate the muscles of the lower legs and thighs, which helps the body support the pelvis and spine in a neutral posture. Forward bias.
This gives the user the freedom to control and maintain their individual balance (which varies depending on user size, gender, and fitness level and the height they are working at).
When the user leans forward or reclines rearward, or tips their head forward or rearward, or extends and contracts their arms, or changes the position of their legs or feet, then these movements will change the user's mass distribution and reaction forces relative to the SI pivot axis. These changes in mass distribution and reaction forces will reorient/rotate the lower back support, pelvic support, thoracic support and thigh support around the SI pivot axis. This reorientation/rotation is controlled by the agonist/antagonist compliant resistance on the pelvic support and the reaction forces applied through the feet to the floor.
This gives the user the freedom to control and maintain their individual balance (which varies depending on user size, gender, and fitness level and the height they are working at).
When the user adjusts the seat height up/down, or extends their feet forward, or tucks their feet under their hips, then these movements will change the thigh/femur angle relative to the pelvis and will change the pressure distribution on the thigh support under the thighs. These changes in thigh angle and thigh support pressure will reorient/rotate the thigh support around the HIP pivot axis. This reorientation/rotation is controlled by the agonist/antagonist compliant resistance on the thigh support, the pressure applied by the thighs to the thigh support, and the reaction forces applied through the feet to the floor. This reorientation/rotation of the thigh support will also change the reaction forces to the pelvic support through the HIP pivot axis and HIP pivot resistance, causing the pelvic support, lower back support, thoracic support and thigh support to reorient/rotate around the SI pivot axis.
This gives the user the freedom to control and maintain their individual balance (which varies depending on user size, gender, and fitness level and the height they are working at).
Thus, the invention provides, among other things, a chair having an upper chair and a lower chair, the upper chair including a pelvic nesting actuator. Various features and advantages of the invention are set forth in the following claims.
This application is a continuation of U.S. application Ser. No. 17/604,261, filed Oct. 15, 2021, which is a national phase filing under 35 U.S.C. 371 of International Application No. PCT/US2020/028319, filed Apr. 15, 2020, which claims priority to U.S. Provisional Application No. 62/834,780, filed Apr. 16, 2019, the entire contents of all of which are incorporated by reference herein.
Number | Name | Date | Kind |
---|---|---|---|
282371 | Rintelman | Jul 1883 | A |
476805 | Mason | Jun 1892 | A |
517929 | March | Apr 1894 | A |
3434755 | Caldemeyer et al. | Mar 1969 | A |
3446532 | Cramer | May 1969 | A |
3464736 | Mizelle | Sep 1969 | A |
3480249 | Lie | Nov 1969 | A |
4099697 | Von Schuckmann | Jul 1978 | A |
4131260 | Ambasz | Dec 1978 | A |
4183579 | Gonzalez | Jan 1980 | A |
4451086 | Seven | May 1984 | A |
4521053 | deBoer | Jun 1985 | A |
4575151 | Edstrom | Mar 1986 | A |
4641885 | Brauning | Feb 1987 | A |
4650249 | Serber | Mar 1987 | A |
D289708 | Rykken | May 1987 | S |
4682814 | Hansen | Jul 1987 | A |
4718726 | Estkowski et al. | Jan 1988 | A |
4765684 | Kvalheim et al. | Aug 1988 | A |
4796950 | Mrotz, III et al. | Jan 1989 | A |
4872727 | Rye | Oct 1989 | A |
4932719 | Gonzalez | Jun 1990 | A |
5244252 | Serber | Sep 1993 | A |
5401077 | Hosoe | Mar 1995 | A |
5435623 | Kapec et al. | Jun 1995 | A |
5536067 | Pinto | Jul 1996 | A |
5558399 | Serber | Sep 1996 | A |
5590930 | Glocki | Jan 1997 | A |
5636898 | Dixon et al. | Jun 1997 | A |
5653505 | Holobaugh, Jr. | Aug 1997 | A |
5716099 | McDiarmid | Feb 1998 | A |
5725276 | Ginat | Mar 1998 | A |
5735574 | Serber | Apr 1998 | A |
6039397 | Ginat | Mar 2000 | A |
6070937 | Ginat | Jun 2000 | A |
6092870 | Desnoyers | Jul 2000 | A |
6120094 | Parent | Sep 2000 | A |
6206335 | Huber et al. | Mar 2001 | B1 |
6386634 | Stumpf et al. | May 2002 | B1 |
6601818 | Larsen | Aug 2003 | B1 |
6669292 | Koepke et al. | Dec 2003 | B2 |
6869142 | Heidmann et al. | Mar 2005 | B2 |
6945602 | Fookes et al. | Sep 2005 | B2 |
6957863 | Heidmann et al. | Oct 2005 | B2 |
7081075 | Sachs | Jul 2006 | B2 |
7134720 | Viger | Nov 2006 | B2 |
7207629 | Goetz et al. | Apr 2007 | B2 |
7234774 | Heidmann et al. | Jun 2007 | B2 |
7234775 | Serber | Jun 2007 | B2 |
7350863 | Engels et al. | Apr 2008 | B2 |
7478878 | Oettinger | Jan 2009 | B2 |
7500718 | Fookes et al. | Mar 2009 | B2 |
7547067 | Keilhauer et al. | Jun 2009 | B2 |
7780230 | Serber | Aug 2010 | B2 |
7841666 | Schmitz et al. | Nov 2010 | B2 |
7878591 | Walker et al. | Feb 2011 | B2 |
8066624 | Stroup | Nov 2011 | B1 |
8419133 | Holt et al. | Apr 2013 | B2 |
8540314 | Fernandez | Sep 2013 | B2 |
8662586 | Serber | Mar 2014 | B2 |
8864230 | Augustat | Oct 2014 | B2 |
8888181 | Perraut et al. | Nov 2014 | B2 |
8944507 | Goetz | Feb 2015 | B2 |
9044097 | Ardrey | Jun 2015 | B1 |
9185973 | Udagawa et al. | Nov 2015 | B2 |
9320318 | Nurse et al. | Apr 2016 | B2 |
D758747 | Lenz et al. | Jun 2016 | S |
9380831 | Craig et al. | Jul 2016 | B2 |
9399415 | Serber | Jul 2016 | B2 |
9402440 | Diepenbrock | Aug 2016 | B2 |
D803592 | Lenz et al. | Nov 2017 | S |
20020190553 | Koepke et al. | Dec 2002 | A1 |
20030001420 | Koepke et al. | Jan 2003 | A1 |
20030071502 | Marshall et al. | Apr 2003 | A1 |
20030132653 | Thole | Jul 2003 | A1 |
20040051362 | Heidmann et al. | Mar 2004 | A1 |
20040195881 | Wells | Oct 2004 | A1 |
20050022305 | Bieganek et al. | Feb 2005 | A1 |
20050029848 | Heidmann et al. | Feb 2005 | A1 |
20050225140 | Kneeshaw | Oct 2005 | A1 |
20060055220 | Heidmann et al. | Mar 2006 | A1 |
20060138840 | Keilhauer et al. | Jun 2006 | A1 |
20060175884 | Jenkins | Aug 2006 | A1 |
20070085408 | Kohani | Apr 2007 | A1 |
20080211277 | Goetz et al. | Sep 2008 | A1 |
20090140567 | Weiss | Jun 2009 | A1 |
20110101748 | Goetz | May 2011 | A1 |
20110175414 | Asbjornsen | Jul 2011 | A1 |
20110304192 | Augustat | Dec 2011 | A1 |
20120216347 | Tundo et al. | Aug 2012 | A1 |
20120304370 | Gianfagna et al. | Dec 2012 | A1 |
20130306831 | Keen et al. | Nov 2013 | A1 |
20150196123 | Buehrer | Jul 2015 | A1 |
20150201758 | Serber | Jul 2015 | A1 |
20150245713 | Desanta | Sep 2015 | A1 |
20160015179 | Bonneywell | Jan 2016 | A1 |
20160073786 | Walker et al. | Mar 2016 | A1 |
20160157618 | Arnett | Jun 2016 | A1 |
20160360889 | Matlin et al. | Dec 2016 | A1 |
20170007026 | Avery | Jan 2017 | A1 |
20170020292 | Walker et al. | Jan 2017 | A1 |
20180020831 | Lenz | Jan 2018 | A1 |
Number | Date | Country |
---|---|---|
1039638 | Oct 1978 | CA |
4239548 | Apr 1993 | DE |
102012212121 | Jan 2014 | DE |
102009010183 | Aug 2018 | DE |
2167947 | Jun 1986 | GB |
S6452536 | Feb 1989 | JP |
2001506149 | May 2001 | JP |
2014004324 | Oct 2004 | JP |
2007268118 | Jan 2014 | JP |
20130096520 | Aug 2013 | KR |
101333318 | Nov 2013 | KR |
8910080 | Nov 1989 | WO |
1997046144 | Dec 1997 | WO |
2012170863 | Apr 2013 | WO |
2014009147 | Jan 2014 | WO |
2014179815 | Nov 2014 | WO |
2017132240 | Aug 2017 | WO |
Entry |
---|
International Search Report with Written Opinion for related Application No. PCT/US2016/043905 dated Nov. 1, 2016 (14 pages). |
International Search Report with Written Opinion for related Application No. PCT/US2020/028319 dated Aug. 25, 2020 (16 Pages). |
Herman Miller Aeron Office Chair Review, website:https://www.youtube.com/watch?v=iN61R6RcZcU, Dated Feb. 21, 2019 (4 Screenshots). |
Best Ergonomic, “Swing Chair”, Website: http://www.swingchair.com Dated Aug. 11, 2016 (6 Pages). |
Extended European Search Report for Application No. 20791550.5 dated Dec. 12, 2022 (7 Pages). |
Number | Date | Country | |
---|---|---|---|
20230049996 A1 | Feb 2023 | US |
Number | Date | Country | |
---|---|---|---|
62834780 | Apr 2019 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 17604261 | US | |
Child | 17979465 | US |