Proper posture is not only important for the spine, but also the pelvic region and shoulders. Sitting without proper posture repeatedly and for long periods of time can eventually lead to chronic back pain, shoulder and neck pain, or even permanent or semi-permanent misalignment of the spine, which may require medical intervention to correct. Additionally, sitting in a hunched over position can affect a person's breathing.
A majority of people work in an office job or another job that requires sitting upright in a chair or seat for extended periods of time, often for more than 8 hours in a single day. Typical seating used by people of all sizes does not adjust to fit each individual's unique sitting needs anthropometrically, biomechanically, or at the general comfort level. General comfort is often tough to quantify but it is common medical knowledge that pain from tissue, joint, muscle, etc. is simply derived from a person's nociceptors. The nociceptor that determines pain in the seated space is known as the mechanoreceptors. The four main types of mechanoreceptors are the Merkel disks for the pressure, the Ruffini corpuscles for the stretch and shear stresses, the Pacinian corpuscles for vibration, and the Meissner's corpuscles primarily providing information about tactile and sensitive changes. The Merkel disks and the Ruffini corpuscles mechanoreceptors are slowly adapting cutaneous mechanoreceptors. For comfort, slowly adapting mechanoreceptors are more critical than fast adapting mechanoreceptors. Therefore, parameters in the interaction zone that may be relevant to comfort are pressure elongation and shear stress. These findings were not published until 2005 and were not examined as relevant to seating comfort until 2020. Thus, previous chair designs trying to apply posterior lifting features to the pelvic and thoracic regions did not take into account that the forces from the back supports were creating an equal and opposite shear force across the seat of the occupant and impacting Ruffini corpuscles.
For example, in U.S. Pat. Nos. 7,040,703, 7,396,082, and 4,981,325, each device tries to apply a force to the sacral and thoracic regions, but do not attempt to counteract that force. This will lead to the pelvis of the occupant sliding forward over time, resulting in an unstable posture, and/or will lead to discomfort caused by a reaction of the Ruffini corpuscles.
Nociceptors are located in the skin, muscles, skeletal structures, and viscera and are responsible for sending pain signals to the brain for a person to process and then take appropriate action. If a chair doesn't fit a user properly, the user may sit awkwardly causing tissue or joint pain. Additionally, the tissue or joint pain often causes the user to move or fidget in the chair. If a chair can adjust to truly fit the size and shape of the user, exert low peak pressure and low shear on the tissue surfaces, and hold the user's pelvis, spine, and head in a neutral posture alignment, the user may experience less pain while sitting, thus achieving greater comfort over time. This is not an easy task, and a solution is desired to achieve the above-mentioned steps for increased comfort over time and improved sitting capabilities or tolerances.
In the state of the art of biomechanical laws for sitting and standing, neutralizing one's pelvis in space will result in establishing a natural lumbar curve and alignment of the mid/upper thoracic region. Applying a force or device directly to L1-L4 does not provide biomechanical advantage in lifting the upper thoracic region and/or have the preferred ability to rotate the pelvis into a neutral state. It can be hard for the human body to tolerate the pressure on the L1-L4 that would be required to lift one's central mass using a lumbar support. Supporting/rotating the pelvis gives a user the biomechanical advantage to rotate the pelvis about its natural pivot point, which is the acetabulum (e.g., socket for femoral head). What is known as natural lumbar curvature can more easily be achieved by simply controlling the angle of one's pelvis. When a person is standing or sitting with correct posture/alignment, the pelvis should be within three degrees of neutrality in a posterior/anterior rotation. The human pelvis when standing and measured between the PSIS and ASIS has a balanced/neutral axis of 7 to 10 degrees. Meaning that the pelvis can travel plus or minus 1.5 degrees (i.e., 1.5 degrees in an anterior direction or 1.5 degrees in a posterior direction) before being defined as coming out of neutrality. When in a neutral (or optimal position), the L5, which is firmly held in place to the pelvis with the iliolumbar ligaments, is stacked upright which also allows the L4, L3, L2, and L1 to have an optimal lumbar curve. As an example, when the pelvis begins to rock forward or backwards, the movement of the pelvis holding L5 causes L4, L3, L2, and L1 to sway out of place. Thus, when the pelvis has a posterior rotation, for example in a slouching posture, the person loses their lumbar curve due to the backwards rotation of the L5 within the pelvis, thereby toppling the other lumbar segments. Angling the pelvis too far in the anterior direction results in excessive lordotic posture and angling the pelvis too far in the posterior direction results in slumped or c-shaped sitting. In lordotic posture, there is typically no disc bulging. However, in slumped posture, the disc pressure increases, resulting in bulging of the discs. This is why keeping a neutral pelvis is seen medically as an optimal outcome for long term healthy sitting. This neutrality is what holds L5 at a certain angle in space. L4-L1 follow this arcuate path establishing natural lumbar curve, giving proper disc spacing. When you rotate the pelvis anteriorly or posteriorly, the angles of L5 and L4 follow the rotation of the pelvis because L5 and L4 have so many surrounding ligaments tying them to the pelvis. Thus, when the angles of L5 and L4 change, the natural hinging between L3, L2, and L1 starts reducing or inducing curvature. The further you rotate the pelvis backwards/posteriorly, the more you lose your natural lumbar curvature. It should be made clear that the pelvis's rotational position in space is what controls flexion or extension of the lumbar spine region, which in turn affects intradiscal pressure. Passive extension of the spine on the posterior side causes intradiscal pressure, this leads the nucleus pulposus to migrate anteriorly and thus relieve pressure on pain sensitive structures of the spine including the posterior longitudinal ligament and annulus fibrosis. Thus, controlling one's posture by articulating the pelvis rotation in space is the preferred medical approach to establishing and supporting a natural lumbar and thoracic curve and proper intradiscal pressure.
It should be made clear that if the pelvis is not held in a neutral state, it is biomechanically impossible to restore natural spinal column alignment throughout the entire spine. This is why holding the pelvis in a neutral state during sitting or standing is the only way to stand or sit without adding disc pressures, stress, muscle imbalance and/or fatigue, and joint pain to the entire trunk of the human body.
A seating configuration is described. The seating configuration includes a seat. The seat includes a feature to retain a user in a specific position on the seat. The seating configuration includes a first back support. The first back support is positioned adjacent a posterior pelvic area of the user. The seating configuration includes a second back support. The second back support is positioned adjacent to the thoracic area of the user. The seat, the first back support, and the second back support together can be configured to create a natural alignment of a spinal column of the user.
Various examples of embodiments of the systems, devices, and methods according to this invention will be described in detail, with reference to the following figures.
It should be understood that the drawings are not necessarily to scale. In certain instances, details that are not necessary to the understanding of the invention or render other details difficult to perceive may have been omitted. It should be understood, of course, that the invention is not necessarily limited to the particular embodiments illustrated herein.
One or more specific embodiments will be described below. In an effort to provide a concise description of these embodiments, not all features of an actual implementation are described in the specification. It should be appreciated that in the development of any such actual implementation, as in any engineering or design project, numerous implementation-specific decisions must be made to achieve the developers' specific goals, such as compliance with system-related and business-related constraints, which may vary from one implementation to another. Moreover, it should be appreciated that such a development effort might be complex and time consuming, but would nevertheless be a routine undertaking of design, fabrication, and manufacture for those of ordinary skill having the benefit of this disclosure.
Additionally, the seat typically has minimal or no support characteristics to hold the inferior surface of one's pelvis 10 laterally and typically also lacks features to prevent shearing on the anterior side of the Ischial Tuberosities (IT's), which reduces sliding of the pelvic area forward and backward. This lack of support results in pelvic collapse and typically leads to the user being in slumped or slouched forward seating position. In addition, a user will unknowingly lean side to side in an attempt to avoid discomfort within their sit bones and/or their spinal column. Leaning and/or fidgeting is a side effect of feedback from the mechanoreceptors (i.e., the Merkel disc and the Ruffini corpuscles) that indicates discomfort or soreness while sitting. If a user's sit bones (IT's) are sore, they may also tend to perch on the front edge of the chair to help alleviate this soreness, which ultimately was caused by high peak pressures on their sit bones. Perching on the edge of the chair may provide temporary relief by lowering the distal end of the user's femurs, thus lifting their pelvis 10. This perching behavior to avoid sit bone pain pulls the user away from any back support feature that could help them sit upright with ease. With no back support, the body will fatigue quickly due to the large amount of muscle groups that need to be activated in order to hold the user in a pelvic/spine neutral position. This is not optimal or comfortable sitting behavior for 6 to 8 hours a day.
As shown in
Moving to the thoracic region 30 of the spine 15, in a normal user's seated posture, as depicted in
Furthermore, most users keep their shoulders 35 in a forward position because the thoracic-cervical region 30 is not properly supported around the T10-T12 segments of the spine 15 by the back support of the example chair in
In addition to the muscle strain and fatigue in the back, shoulders 35 and neck 45, a typical chair 5 also causes excess pressure on the ischial tuberosity 50 (may colloquially be referred to as sit bones). The seat 20 of the chair 5 may also cause shear pain directly beneath and/or on the anterior side of the ischial tuberosities 50 within the tissue, muscle, and fat that is compressed between the seat surface and ischial tuberosities. This shear pain (i.e., response from the Ruffini corpuscles mechanoreceptors) is induced when a user is sliding in a seated plane; not only is this uncomfortable, it is also dangerous and reduces blood flow, which destroys one's cells more quickly than pressure alone (i.e., a response from the Merkel disc mechanoreceptors). Shear within a seating system will also trigger a nociceptive pain signal more abruptly than pain or discomfort caused by pressure. Pressure pain and/or shear pain will cause the user to frequently re-adjust to find a more comfortable sitting position regardless of how optimal a back support may be.
Sitting too long with the spine 15 in improper seated posture leads to chronic pain and potential back injury (i.e., repetitive stress injury). Unfortunately, sitting for long periods of time is unavoidable for many people, for example, people working in offices, farmers, people operating heavy machinery or public transportation, etc. Thus, it is important that the chair back(s), in combination with the seat in which the user is expected to sit for extended periods of time, provides proper support and reduces peak pressures within all of the support surfaces to allow the user to rest and/or focus on a task. Such a combination of a seat and chair back(s) also encourages proper posture for the entire spine 15 while again not sending nociceptive pain signals to the brain.
The example seat configuration 55 includes a seat 60 that includes a contoured pelvic well 95 and inclined femoral surface 97, both of which are retaining features that prevent forward migration of the user's pelvis, allowing an input of the pelvic-sacral-lumbar support 65 to rotate the pelvis upward and hold the pelvis in the neutral state. The pelvic well 95 and the inclined femoral surface 97 provide a force in the posterior and downward direction (from the anterior side of the pelvis) to counteract the force of the first and thoracic-cervical supports in the anterior direction (from the posterior side of the pelvis). Thus, the pelvic well 95 and inclined femoral surface 97 maintain the position of the user toward the rear of the seat 60 to keep the user's pelvis in contact with the pelvic-sacral-lumbar support 65 and keep the user's thoracic region in contact with the thoracic-cervical support 70. In fact, a study has shown that a contoured seat surface has a greater effect on uniformity of pressure distribution and that a lower peak pressure implied an improvement of the user's comfort on the seat. Thus, the example seat 60 including the pelvic well 95 and inclined femoral surface 97 provides greater comfort by reducing the seating pressures in addition to maintaining the position of the user so that the user can feel the full effect of the pelvic-sacral-lumbar and thoracic-cervical supports 65, 70.
The illustrated construction of
Alternatively, a seat 60 and back supports 65, 70 as described herein may be used in other environments. For example, the configuration 55 of the seat 60 and back supports 65, 70 may be used in a vehicle, an airplane, an entertainment venue, in industrial and/or farming equipment, or generally in any type of chair or seat in which the user is expected to sit in a plurality of positions for long periods of time, ideally with positive comfort over time. The design of the seat 60 and the pelvic-sacral-lumbar and/or thoracic-cervical supports 65, 70 can be adapted for use in a plurality of other seating situations, for example, by attaching the seat 60 to a different base and the pelvic-sacral-lumbar and/or thoracic-cervical supports 65, 70 to a different type of back frame and/or seat. The configuration 55 of the seat 60 and back supports 65, 70 is such that the proper curvature of the spine is established and is comfortable for seated tasks, such as using a computer, operating heavy machinery, or driving, but may also be beneficial for sitting in a comfortable upright position as a passenger (e.g., of public transportation, a plane, etc.) or watching a movie, performance, or game in theater/stadium style seating. The seat 60 may also be used with solutions for mobility challenged users (e.g., wheelchairs (both manual and power), feeder seats, strollers, bathing chairs, adaptive car seats, other durable medical equipment, etc.). The pelvic-sacral-lumbar support and/or the thoracic-cervical support may also be used with such mobility devices within the durable medical equipment industry. For example, the pelvic-sacral-lumbar support 65 and/or thoracic-cervical support 70 may be pivotally coupled to a frame of a wheelchair or power chair to support a user's pelvis while in the wheelchair. The example cushion or seat 60 described herein may also be used with the wheelchair instead of a traditional cushion or flat seat.
The example pelvic-sacral-lumbar support 65 has a curved profile, as shown in the perspective view of
In addition to the upward angles toward the edges of the pelvic-sacral-lumbar support 65, in some examples the entire pelvic-sacral-lumbar support 65 may be pretensioned with an upward angle bias (e.g., using a spring or other biasing mechanism) that is reduced in angle as the user sits so that the central part of the pelvic-sacral-lumbar support 65 appropriately fits the user and also lifts the pelvis and/or pelvic-sacral-lumbar region. That is, the pelvic-sacral-lumbar support 65 may be pivotable about a horizontal axis so that the pelvic-sacral-lumbar support 65 can pivot to adjust to fit multiple shapes and sizes of users, and an initial position of the pelvic-sacral-lumbar support 65 is biased with an upward angle. The pelvic-sacral-lumbar support 65 may also be adjusted and locked to different angles to fit different sizes of users.
However, in some examples, the pelvic-sacral-lumbar support 65 is pivotably fixed (e.g., does not pivot about the connection to the support arm). A pivotably fixed pelvic-sacral-lumbar support 65 may be easier to manufacture and/or may be more durable because a repetitive stress point is removed from the chair. Additionally, the angle of the pelvic-sacral-lumbar support 65 that is comfortable for the majority of users does not significantly change throughout the range of forward and backward motion (e.g., seat depth adjustment, a pelvic angle adjustment) of the pelvic-sacral-lumbar support 65. The upward bias of the pelvic-sacral-lumbar support 65 may be more critical in a chair with a larger range of motion of the pelvic-sacral-lumbar support.
The pelvic-sacral-lumbar support 65 may be positioned just above the seat 60 to facilitate the contact with the pelvic-sacral-lumbar region 10. The curved shape in the transverse plane of the pelvic-sacral-lumbar support 65 not only lifts and supports the pelvic-sacral-lumbar region 10, but also provides lateral stability to prevent the user from leaning to one side or the other, thereby maintaining the user in an, upright position. The shape and positioning of the pelvic-sacral-lumbar support 65 ensures that the pelvic-sacral-lumbar region 10 is maintained in a natural and neutral seated position.
In some example constructions, the pelvic-sacral-lumbar support 65 is rotationally fixed (e.g., fixed about a horizontal axis, not pivotable). In example constructions in which the pelvic-sacral-lumbar support 65 is fixed, the upward and inward angles of the edges of the pelvic-sacral-lumbar support 65 are set such to accommodate as broad a range of body types and sizes as possible. A fixed pelvic-sacral-lumbar support 65 may be advantageous in some implementations of the example pelvic-sacral-lumbar support 65, such as for use in environments where the adjustability/customization of the location of the pelvic-sacral-lumbar support 65 may not be feasible (e.g., theater seating, seating on public transit or planes, etc.). Additionally, the fixed pelvic-sacral-lumbar support 65 may be used in seating systems where only one back support is desired or feasible.
In alternative example constructions, the pelvic-sacral-lumbar support 65 is pivotable around a horizontal axis (e.g., an x-axis) at a pivot point 96 (see
In some example constructions, the height of the pelvic-sacral-lumbar support 65 relative to the seat 60 is adjustable. The height of the pelvic-sacral-lumbar support 65 may be adjustable by the user to better fit the user's body such that the pelvic-sacral-lumbar support 65 is substantially in the ideal position to properly support and lift the user's pelvic-sacral-lumbar region 10. For example, a taller user (e.g., a user above an average height for an adult) may need the pelvic-sacral-lumbar support 65 at a different relative height than a shorter user (e.g., a user below an average height for an adult). Thus, an adjustable height construction of the pelvic-sacral-lumbar support 65 enables the pelvic-sacral-lumbar support 65 to accommodate a broader range of users to effectively lift and support the user's pelvic-sacral-lumbar region 10. Additionally or alternatively, the pelvic-sacral-lumbar support 65 may move from the back of the seat toward the front of the seat to adjust effective seat depth and to accommodate different heights and sizes of users.
The example seating configuration 55 also includes a second example back support (e.g., a thoracic-cervical support) 70, as show in
In a typical seated position, rolling the shoulders forward is easier than keeping the shoulders back because keeping the shoulders back for an extended period of time creates strain and fatigue in the upper back and shoulder muscles, particularly the rhomboid muscles and the trapezius muscle. The thoracic-cervical support 70 contacts the thoracic-cervical region, specifically the T10-T12 segments of the spine, and provides support to encourage proper alignment of the thoracic-cervical region of the spine. Thus, when properly adjusted, the thoracic-cervical support 70 is capable of preventing anterior lean/tilt/flexion of the thoracic region and encourages the shoulders to retract, helping the user to maintain an upright alignment. This allows the user to be able to sit in a position with proper posture for an extended period of time without muscle fatigue, discomfort, soreness, or muscle pain. The example thoracic-cervical support 70 makes it easier for the user to maintain proper posture, thus promoting and enabling good spinal health for extended periods of time. The vestibular system, which controls the position of the body at rest and provides the brain with information relating to motion, head position, and spatial orientation works in tandem with the thoracic-cervical support 70 to help neutrally align the thoracic region and comfortably position the head. Due to every person's unique sense of their center of balance, each user has the ability to optimize the location of the thoracic-cervical support 70 to find the proper balance point of their head. A person's sense of balance relies on a series of signals to the brain from several organs and structures in their body. The part of the ear that assists in balance is known as the vestibular system. When a person moves, the vestibular system detects mechanical forces, including gravity, that stimulate the semicircular canals and the otolithic organs (Vestibular System). These organs work with other sensory systems in your body, such as the vision and the musculoskeletal sensory system, to control the position of a person's body at rest or in motion. Without the adjustable thoracic-cervical support, a balance point cannot be achieved for each individual.
The illustrated thoracic-cervical support 70 has a substantially trapezoidal shape (e.g., a modified trapezoidal shape with rounded corners and curved edges). The back of the user rests on the center portion. The left and right side portions 110, 115 are angled inward to contact at least a portion of the user's ribs (e.g., a portion of at least the two lower ribs) to promote lateral stability (i.e., to prevent the user from leaning to one side or the other, thereby maintaining the user in an upright position). Even a slight contact of the ribs is sufficient to laterally support the user.
The left and right angled edges may be substantially straight, but still allow for more movement of the user's arms and shoulders than a typical chair due to the substantially trapezoidal shape of the thoracic-cervical support 70. Alternatively, the left and right angled edges may have a curved or cutout portion to allow the user to more easily move their arms into a retracted or reaching position (e.g., to reach for something to one side, to stretch, etc.). In either construction, the thoracic-cervical support 70 provides support to the scapulas to keep the scapulas pushed in. Specifically, the trapezoidal shape falls within the thoracic cavity of the user. Anything wider than the thoracic cavity will interfere with the arms or elbows of the user, not allowing for full retraction or reach of the arms of the user.
A top edge 120 of the example thoracic-cervical support 70 is thicker than the bottom portion of the thoracic-cervical support 70 and is angled inward. The example top edge 120 helps promote the correct curvature of the thoracic-cervical spinal region 30. However, in alternative examples, the top edge 120 may be the same thickness as the rest of the thoracic-cervical support 70 and may not be angled forward. In such examples, the thoracic-cervical support 70 is still effective to support the user's thoracic-cervical region 30 in a proper seated posture with minimal muscle engagement. Even without the inwardly curved upper edge, the user is able to easily maintain shoulder retraction and the proper curve of their thoracic-cervical spinal region 30 due to the pelvic well 95 in the seat 60 and the pelvic-sacral-lumbar support 65 providing the foundation for proper posture for the entire spine 15.
The example thoracic-cervical support 70 can be moved in an inward (anterior) and outward (posterior) direction relative to the seat 60. Additionally, the thoracic-cervical support 70 may have an adjustable height. Preferably, the height adjustment is done through the center support of the chair (e.g., using a telescoping center support that is attached to a back support). However, the height adjustment can be made at the back support 70 (e.g., using multiple different holes through which a pin can be placed, or other similar adjustable feature, to adjust the height of each back supports 65, 70). The adjustment allows the thoracic-cervical support 70 to be positioned in the correct spot to promote proper anatomical alignment of the user without significant engagement of the user's core and back muscles. More specifically, the forward and backward adjustment ensures that the thoracic-cervical support 70 maintains proper posture by keeping the user balanced over the pelvic-sacral-lumbar region 10. The height adjustment ensures that the inwardly angled sides are in contact with at least a portion of the lower ribs and not so high as to make moving the shoulders difficult.
The thoracic-cervical support 70 may also pivot about a horizontal axis at a pivot point 98 (see
To further aid in proper pelvic-sacral-lumbar support and alignment, the example seating configuration 55 includes a seat 60 with the pelvic well 95 and inclined femoral surface 97 formed in the structure of the seat 60, as shown in
In the example construction depicted in
The pelvic well 95 is positioned adjacent a back edge 125 of the seat 60 where a user's pelvis would be positioned when the user is sitting in an upright position with proper posture. The example pelvic well 95 may have a shape corresponding to a shape of the pelvis and gluteus muscles when in a seated position. For example, sides 130, 135 (e.g., left and right sides of the pelvic well adjacent left and right sides of the seat) of the pelvic well 95 may be curved in a similar manner as a curve of a user's hips and/or gluteus muscles when in a seated position. This side edge/curve extends to a front edge 140 of the seat 60, forming an elevated edge along the entire length of each the left and the right sides of the seat 60. The front edge of the seat is at a height above the pelvic well to create increased pressure on the distal end of the femurs, thus increasing pressure distribution area as well as decreasing pressure on the IT's. A back edge of the pelvic well 95 adjacent to the back edge of the seat may be curved to correspond to a curve of the user's pelvic-sacral-lumbar region 10 and gluteus muscles, which further increases the pressure distribution area and helps assist the lifting of the pelvis in conjunction with the input from the pelvic-sacral-lumbar support 65.
The slope toward the pelvic well 95 encourages the proper placement of the pelvis in the pelvic well 95. Additionally, the pelvic well 95 and inclined femoral surface 97 may help relieve pressure or shear underneath and surrounding the region of the IT's. The shape of the pelvic well 95 helps cradle and support the user's lower pelvic region or sitting surface and maintain the position of the user's pelvis on the seat 60 such that the pelvic support 65 can maintain contact with the pelvic-sacral-lumbar region 10. Additionally, the pelvic well 95 and inclined femoral surface 97 hold the user in place on the seat 60, reducing or preventing sliding of the user while the user is sitting in the seat 60. Additionally, the left and right edges are raised to help the user position themselves in the center of the seat so that the pelvic-sacral-lumbar and thoracic-cervical supports 65, 70 can work properly to support the user.
In addition to the pelvic well 95, the front edge of the seat 60 may include a reverse tapered edge 142 (e.g., an edge that has a bottom surface that is undercut at an angle). The front edge may be tapered backward to act as a relief cut that more closely follow the popliteal fossa downward along the calf muscle. The relief cut helps mitigate contacting these areas, thus reducing the chance of restricting blood flow to one's lower extremities. The design of the front edge of the support surface allows the front edge of the seat to collapse under the weight of the user's legs without the edge of the seat pan contacting and causing pressure on the user's lower extremities. The front edge of the seat pan may also be as low as possible to allow plenty of space for the foam to crush under the weight of the user's legs without coming in contact of the hard front edge, which would cause a sharp pressure to the user's skin that could lead to a pressure injury. Alternatively, the front edge of the seat maybe rounded, squared off, or a waterfall edge.
One or more of the disclosed embodiments, alone or in combination, may provide one or more technical effects including promoting proper ergonomic posture in a way that is comfortable for extended periods of time for a user sitting in a seat configuration described herein. The technical effects and technical problems in the specification are exemplary and are not limiting. It should be noted that the embodiments described in the specification may have other technical effects and can solve other technical problems.
As utilized herein, the terms “approximately,” “about,” “substantially,” and similar terms are intended to have a broad meaning in harmony with the common and accepted usage by those of ordinary skill in the art to which the subject matter of this disclosure pertains. It should be understood by those of skill in the art who review this disclosure that these terms are intended to allow a description of certain features described and claimed without restricting the scope of these features to the precise numerical ranges provided. Accordingly, these terms should be interpreted as indicating that insubstantial or inconsequential modifications or alterations of the subject matter described and claimed are considered to be within the scope of the invention as recited in the appended claims.
It should be noted that references to relative positions (e.g., “top” and “bottom,” “left” and “right”) in this description are merely used to identify various elements as are oriented in the Figures. It should be recognized that the orientation of particular components may vary greatly depending on the application in which they are used.
For the purpose of this disclosure, the term “coupled” means the joining of two members directly or indirectly to one another. Such joining may be stationary in nature or moveable in nature. Such joining may be achieved with the two members or the two members and any additional intermediate members being integrally formed as a single unitary body with one another or with the two members or the two members and any additional intermediate members being attached to one another. Such joining may be permanent in nature or may be removable or releasable in nature.
It is also important to note that the construction and arrangement of the system, methods, and devices as shown in the various examples of embodiments is illustrative only, and not limiting. Although only a few embodiments have been described in detail in this disclosure, those skilled in the art who review this disclosure will readily appreciate that many various alternatives, modifications, variations, improvements and/or substantial equivalents, whether known or that are or may be presently foreseen, are possible (e.g., variations in sizes, dimensions, structures, shapes and proportions of the various elements, values of parameters, mounting arrangements, use of materials, colors, orientations, etc.) without materially departing from the novel teachings and advantages of the subject matter recited. For example, elements shown as integrally formed may be constructed of multiple parts or elements show as multiple parts may be integrally formed, the operation of the interfaces may be reversed or otherwise varied, the length or width of the structures and/or members or connector or other elements of the system may be varied, the nature or number of adjustment positions provided between the elements may be varied (e.g. by variations in the number of engagement slots or size of the engagement slots or type of engagement). The order or sequence of any process or method steps may be varied or re-sequenced according to alternative embodiments. Other substitutions, modifications, changes, and omissions may be made in the design, operating conditions, and arrangement of the various examples of embodiments without departing from the spirit or scope of the present inventions. Therefore, the invention is intended to embrace all known or earlier developed alternatives, modifications, variations, improvements and/or substantial equivalents.
This application claims the benefit of U.S. Provisional Patent Application No. 63/221,669 filed Jul. 14, 2021, entitled “SEAT AND BACK FOR A CHAIR”, the entire content of which is hereby incorporated by reference herein in its entirety.
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