HIGHCHAIR FOOTREST

FIELD OF TECHNOLOGY

Aspects and embodiments of the disclosure are directed generally to an infant highchair. In particular, aspects and embodiments of the disclosure are directed to an infant highchair having an adjustable footrest.

SUMMARY

In accordance with one aspect, there is provided an infant highchair comprising a base having a plurality of legs, and a footrest positioned between a first and a second leg of the base, the footrest comprising two rotators configured to rotate the footrest into a first position for foot support and a second position for foot support.

In some embodiments, the footrest has a first planar surface opposite a second planar surface. The rotators may be configured to rotate the footrest into the first position having the first planar surface facing up and into the second position having the second planar surface facing up.

The highchair may comprise a locking mechanism configured to lock the footrest in the first position and in the second position.

The highchair may comprise a locking mechanism configured to lock the footrest in more than two positions for foot support.

In some embodiments, the footrest comprises a bottom support and two lateral supports, each lateral support positioned adjacent a distal end of the bottom support, each rotator positioned to rotatably connect a respective lateral support and an adjacent leg of the base.

In some embodiments, the bottom support is independently rotatable with respect to the two lateral supports.

In some embodiments, the bottom support is fixed with respect to the two lateral supports.

The highchair may comprise two locking mechanisms configured to lock the footrest in the first position and in the second position, each locking mechanism associated with a respective rotator.

In some embodiments, each locking mechanism comprises at least one peg and at least one slot positioned to receive the peg preventing rotation of the respective rotator.

In some embodiments, each rotator comprises a ring having a lip and a plate having a channel, the lip being rotatably connected to the channel.

In accordance with another aspect, there is provided an infant highchair comprising a base having a plurality of legs, and a footrest positioned between a first and a second leg of the base, the footrest comprising a bottom support having a first planar surface opposite a second planar surface and two rotators configured to rotate the footrest at least 180°.

In some embodiments, the rotators are configured to rotate the footrest into a first position having the first planar surface facing up and into a second position having the second planar surface facing up.

In some embodiments, the footrest comprises two lateral supports, each lateral support positioned adjacent a distal end of the bottom support, each rotator positioned to rotatably connect a respective lateral support and an adjacent leg of the base.

In some embodiments, each rotator comprises a ring having a lip, the ring being fixed to the adjacent leg of the base, and a plate having a channel, the plate being fixed to the respective lateral support, wherein the lip is rotatably connected to the channel.

In some embodiments, the bottom support is fixed with respect to the two lateral supports.

The highchair may comprise a locking mechanism configured to lock the footrest in at least one position for foot support.

In some embodiments, the locking mechanism is configured to lock the footrest in a first position having the first planar surface facing up and in a second position having the second planar surface facing up.

In accordance with another aspect, there is provided an infant highchair comprising a base having a plurality of legs, and a footrest positioned between a first and a second leg of the base, the footrest comprising two rotators configured to rotate the footrest, two locking mechanisms configured to lock the footrest in a first position for foot support and a second position for foot support, and two release actuators, each release actuator configured to release a respective locking mechanism.

In some embodiments, each release actuator is positioned adjacent a respective rotator.

In some embodiments, at least one release actuator is a spring-loaded button. In some embodiments, both release actuators are spring-loaded buttons.

In some embodiments, each locking mechanism comprises at least one peg operably connected to a respective release actuator and at least one slot positioned to receive the peg preventing rotation of a respective rotator.

In some embodiments, each locking mechanism comprises more than one slot positioned to receive the peg, each slot associated with a position for foot support.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings are not intended to be drawn to scale. In the drawings, each identical or nearly identical component that is illustrated in various figures is represented by a like numeral. For purposes of clarity, not every component may be labeled in every drawing. In the drawings:

FIG. 1 is a front perspective view of a highchair, according to one embodiment;

FIG. 2A is a side view of a highchair having the footrest in an upper position, according to one embodiment;

FIG. 2B is a side view of a highchair having the footrest in a lower position, according to one embodiment;

FIGS. 3A-3D are side perspective views of a portion of a highchair showing the transition of the footrest from an upper position (FIG. 3A) to a lower position (FIG. 3D), according to one embodiment;

FIGS. 4A-4B are enlarged views of a portion of a highchair, in accordance with certain embodiments;

FIG. 5 is a transparent view of the portion of the highchair of FIG. 4A, showing interior components of the portion of the highchair, according to one embodiment;

FIG. 6 is a front perspective view of a highchair, showing an arc of rotation of the footrest, according to one embodiment;

FIGS. 7A-7E are side perspective views of a portion of a highchair showing the transition of the footrest from a lower position (FIG. 7A), through intermediate positions (FIGS. 7B-7D), to a higher position (FIG. 7E), according to one embodiment;

FIGS. 8A-8E are transparent side views of the portion the highchair of FIGS. 7A-7E, showing interior components, according to one embodiment;

FIG. 9 is a front view of a highchair including a harness, according to one embodiment;

FIG. 10 is a front perspective view of a portion of a highchair including a harness, according to one embodiment; and

FIGS. 11A-11B are photographs showing an exemplary child seat and harness, according to one embodiment.

DETAILED DESCRIPTION

The disclosure relates generally to a highchair. Highchairs are typically used to support children in an upright position. The highchair disclosed herein may be fitted to support children at various developmental stages, including a newborn, infant, or toddler. In certain embodiments, the highchair may be designed or fitted to support an infant. The highchair may include one or more inserts, such as a booster or head and/or body support cushion, to provide appropriate support for a child of the target developmental stage. While the disclosure refers generally to a highchair, it should be understood that the embodiments described herein may be used with a chair fitted to support older children, for example, a preschooler or school-age child.

FIG. 1 is a perspective view of a highchair as described herein. The highchair may include a seat 100 having a backrest and a bottom surface. The backrest may be defined as a substantially vertical semi-planar structure of the seat 100 for lumbar, neck, and/or head support. The bottom surface may be defined as a substantially horizontal semi-planar structure of the seat 100 for seated support. The backrest and/or bottom surfaces of the seat 100 may optionally be concave or comprise concave portions to provide ergonomic support.

The seat 100 may be fixed or mountable to one or more bases. In FIG. 1, the seat is shown mounted to a free-standing base including four legs, 400a-400d. In some embodiments, the seat 100 may be mountable to a structure or a supportable base. The seat 100 may be a component of a modular child seating system. The modular child seating system may include the seat 100 and a base, such as the free-standing base or a supportable base. The supportable base may be fixed or mountable to a support structure or the seat 100 may be mountable to the support structure. In some embodiments, the seat 100 may comprise at least one connection mechanism configured to mate with a corresponding connection mechanism of the free-standing base and/or a corresponding connection mechanism of the supportable base.

The seat 100 may be formed of a plastic material. Exemplary plastic materials include nylon, acrylic, polypropylene, and polyethylene (such as cross-linked polyethylene (PEX)). Other plastics, such as hard plastics, may be used. In some embodiments, the plastic may be selected to be substantially non-porous for easy cleaning. In some embodiments, the plastic material may be reinforced with a metal core. Exemplary metal materials include aluminum and stainless steel. Other metal reinforcement materials may be used. The seat 100 may comprise elements formed of a flexible or semi-flexible fabric material. For example, a horizontal crossbar or vertical crossbar may be formed of a fabric material. In some embodiments, the seat 100 may comprise an insert (not shown) formed of a fabric material, such as a booster or cushion. Exemplary fabric materials include polyester, nylon, and blends thereof. Other fabric materials may be used.

The highchair may comprise a footrest 600. The footrest 600 may be positioned between first and second legs of the base, for example, legs 400a, 400b (FIG. 1). The footrest 600 may be configured into more than one position for foot support. In certain exemplary embodiments, the footrest 600 may be adjusted into a first position for foot support (FIG. 2A) and a second position for foot support (FIG. 2B). In exemplary embodiments, the footrest 600 may be rotated between the first position and the second position. For example, the entire footrest 600 or at least a portion of the footrest 600 may be rotated between the first position and the second position. In other embodiments, the footrest 600 may be lowered or elevated between the first position and the second position. While the description relates generally to first and second positions for foot support, it should be understood that, in certain embodiments, the footrest 600 may be configured into more than two positions for foot support, for example, three, four, five, six, or more positions for foot support.

The first position for foot support and the second position for foot support are similar, except that the footrest 600 has a different height (distance from the seat 100) at each position. Thus, children of different heights may comfortably use the same highchair, or the footrest 600 may be adjusted into a lower position once the child grows out of the higher position. The footrest 600 position may be selected to provide a footrest 600 height (distance from the seat 100) appropriate for use by a child of the target developmental stage when seated in the highchair. In some embodiments, the first (lower) position may be at least 24 inches lower than the second (highest) position, and thus at least 24 inches farther from the seat 100. For instance, the first position may be 24-18 inches lower, 18-12 inches lower, or 12-6 inches lower than the second position.

The footrest 600 may have a bottom support 630. The bottom support 630 may be defined as an elongated planar structure for foot support. The bottom support 630 may have a first planar surface 632 for foot support. In some embodiments, the bottom support 630 may have a second planar surface 634 for foot support opposite the first planar surface 632. The footrest 600 may have a first lateral support 640a and a second lateral support 640b. Each lateral support 640a, 640b may be positioned at a distal end of the footrest 600, for example, adjacent a distal end of the bottom support 630. Thus, the bottom support 630 may extend between opposite lateral supports 640a, 640b. The lateral supports 640a, 640b may be positioned to connect the footrest 600 to the legs 400a, 400b, for example, between the bottom support 630 and the legs 400a, 400b.

The lateral supports 640a, 640b may have an elongated profile. For instance, the lateral supports may have a length greater than their width and depth. Along the length dimension, the lateral supports 640a, 640b may have a first end opposite a second end. The first end may be connected to the bottom support 630. The second end may be connected to a respective leg 400a, 400b of the base.

The lateral supports 640a, 640b may comprise a portion extending between the first end and the second end. The portion between the first end and the second end may be dimensioned to define a height difference between the first position and the second position of the footrest 600. The height difference may be approximately 2× the dimension between the first end and the second end of the lateral support 640a, 640b. In some embodiments, the dimension between the first end and the second end may be at least 12 inches, for example, 12-9 inches, 9-6 inches lower, or 6-3 inches.

The dimensions of the footrest 600, for example, lateral support 640a, 640b (length, thickness, pivot point, diameter of the arc of rotation, etc.) may be selected based on the target developmental stage of the child. Each dimension may have an effect on the footrest 600 height (distance from the seat 100). Thus, the dimensions may be selected to be appropriate for use by the child of the target developmental stage when seated in the highchair. In certain exemplary embodiments, the dimensions may be selected to provide an appropriate footrest 600 height (in the first position and in the second position) for an average toddler (e.g., 1-3 years of age).

In some embodiments, the lateral supports 640a, 640b may be fixed to the bottom support 630. For instance, the first end of each lateral support 640a. 640b may be fixed to a corresponding end of the bottom support 630. In these embodiments, the bottom support 630 is not independently rotatable with respect to the lateral supports 640a, 640b. The lateral supports 640a, 640b may be substantially perpendicular to the bottom support 630. Alternatively, the lateral supports 640a, 640b may form a non-perpendicular angle with the bottom support 630. In other embodiments, the first end of each lateral support 640a, 640b may be rotatably connected to a corresponding end of the bottom support 630. In these embodiments, the bottom support 630 may be independently rotatable with respect to the lateral supports 640a, 640b.

Each lateral support 640a, 640b may be rotatably connected to the corresponding leg 400a, 400b. The second end of the lateral support 640a, 640b may be rotatably connected to the corresponding leg 400a, 400b. Thus, the lateral support 640a, 640b may be configured to rotate about a connection point with the corresponding leg 400a, 400b, also referred to as a “pivot point” herein.

The footrest 600 may be configured into the first (lower) position for foot support by rotating the lateral support 640a. 640b down leg 400a, 400b, lowering the bottom support 630. The footrest 600 may be configured into the second (higher) position for foot support by rotating the lateral support 640a, 640b up leg 400a, 400b, raising the bottom support 630. In general, the first planar surface 632 may be used in the first position for foot support. As shown in FIG. 2A, in the first position for foot support the first planar surface 632 is facing up. This arrangement may be used whether the bottom support 630 is fixed to the lateral supports 640a, 640b or rotatably connected to the lateral supports 640a, 640b.

In some embodiments, the second planar surface 634 may be used in the second position for foot support. As shown in FIG. 2B, after a rotation from the first position, in the second position for foot support the second planar surface 634 is facing up and the first planar surface 632 is facing down. This arrangement may be used when the bottom support 630 is fixed to the lateral supports 640a. 640b. In such a configuration, the rotation of the footrest resembles a swing. For the rotation, the entire footrest 600 (bottom support 630 and lateral supports 640a, 640b) is flipped to transition from the first position with the first planar surface 632 facing up to the second position with the second planar surface 634 facing up. In this embodiment, the single point of rotation (shown as release actuators 650a, 650b, FIGS. 3A-3D) is the second end of the lateral supports 640a, 640b, which is rotatably connected to the legs 400a, 400b.

In some embodiments, the first planar surface 632 is also used in the second position for foot support. This arrangement may be used when the bottom support 630 is rotatably connected to the lateral supports 640a, 640b, for example, when the bottom support 630 is independently rotatable with respect to the lateral supports 640a, 640b. As shown in FIGS. 7A-7E, the lateral supports 640a. 640b rotate about the rotatable connection with the legs 400a, 400b while the bottom support 630 simultaneously rotates about the rotatable connection with the lateral supports 640a, 640b to maintain planar surface 632 facing up.

In this embodiment, the footrest includes two points of rotation (FIGS. 8A-8E), the first point of rotation (shown as rotator 610) is the second end of the lateral supports 640a, 640b, which is rotatably connected to the legs 400a, 400b, and the second point of rotation (shown as rotator 710) is the first end of the lateral supports 640a, 640b, which is rotatably connected to the bottom support 630. In some embodiments, the bottom support 630 may have only the first planar surface 632 for foot support. The opposite surface of the bottom support 630 may be rounded or otherwise not configured, dimensioned, or reinforced for foot support. In other embodiments, the bottom support 630 may still have two opposite planar surfaces 632, 634. The user may select whether to rotate the bottom support 630 for use of the first planar surface 632 for foot support in the first and second positions or not rotate the bottom support 630 for use of the second planar surface 634 for foot support in the first or second position.

The transition path between the first and second positions may define an arc of rotation (FIG. 6). The arc of rotation may be defined as the path taken by the first end of the lateral support 640a, 640b (connected to the bottom support 630). The first (lowest) position may be at least 150° from the second (highest) position along the arc of rotation. For example, the first position may be 150°-160°, 160°-170°, 170°-180°, or 180°-190° from the second position. In some embodiments, additional intermediate positions may exist between the first and second positions.

In some embodiments, the footrest 600 may rotate at least 150°. For example, the footrest 600 may rotate at least 160°, at least 170°, at least 180°, at least 190°, at least 200°, at least 210°, at least 220°, at least 230°, at least 240°, or more. In certain embodiments, the footrest 600 may rotate 360°. The footrest 600 may rotate less than 360º, less than 300°, less than 270°, less than 240°, less than 210°, or less than 180°.

In some embodiments, the bottom support 630 may independently rotate at least 150°. For example, the bottom support 630 may rotate at least 160°, at least 170°, at least 180°, at least 190°, at least 200°, at least 210°, at least 220°, at least 230°, at least 240°, or more. In certain embodiments, the bottom support 630 may rotate 360º. The bottom support 630 may rotate less than 360º, less than 300°, less than 270°, less than 240°, less than 210°, or less than 180°.

In other embodiments, the lateral support 640a. 640b may be fixed to the respective leg 400a, 400b and/or the footrest may lack a point of rotation. The bottom support 630 may be slidably engaged with the lateral support 640a, 640b. The bottom support 630 may be positioned to transition between the first position and the second position by being lowered and elevated along the lateral supports 640a, 640b. In this embodiment, a lower end of the lateral support 640a, 640b may be associated with the first (lower) position and an upper end of the lateral support 640a, 640b may be associated with the second (higher) position.

Thus, in some embodiments, the bottom support 630 may be positioned on a track fixed to the lateral supports 640a, 640b. Each lateral support 640a, 640b may have a corresponding track. The track may be a vertical track. The track may define a channel protruding from the lateral supports 640a. 640b or embedded in the lateral supports 640a, 640b. The track may extend vertically, up and down along at least a portion of the lateral supports 640a, 640b. The bottom support 630 may be fixed to wheels or chains movable along the tracks. In some embodiments, the track may comprise a slidable cover to prevent food and other debris from contacting the track.

The footrest 600 may comprise one or more rotators 610. For example, the footrest 600 may comprise two rotators, three rotators, four rotators, or more. Rotators 610 may be positioned at each point of rotation of the footrest 600. The rotator 610 may be configured to rotate the footrest 600 into the first and second positions. The rotator 610 may be defined as a mechanical joint for enabling rotation of one part relative to another. One exemplary rotator joint is formed between rotator ring 610 (FIG. 4A) and rotator plate 612 (FIG. 4B). As shown in FIGS. 4A-4B, exemplary rotator ring 610 is positioned on leg 400a, while rotator plate 612 is positioned on lateral support 640a. Similar rotators may be positioned between leg 400b and lateral support 640b, and at other rotatable connections around the highchair.

Rotator ring 610 may comprise a lip 614 configured to fit into and rotate about a corresponding channel 616 on the rotator plate 612. The channel 616 may be a circular channel. The lip 614 may be dimensioned to extend around all or a portion of the circumference of the rotator ring 610. In some embodiments, the lip 614 may be formed of one or more flanges. The exemplary lip 614 shown in FIG. 4A is formed of two flanges. In some embodiments, the lip 614 is fixed in position. In other embodiments, the lip 614 is retractable for removal of the rotator 610 from the rotator plate 612. In some embodiments, for example, as shown in FIGS. 4A-4B, the channel 616 comprises openings for removal of the rotator 610 from the rotator plate 612. In other embodiments, the channel 616 is free of such openings. Thus, in some embodiments, the footrest 600 is removable from the legs 400a, 400b. In other embodiments, the footrest 600 is not removable from the legs 400a, 400b.

The rotator joint may be formed of corresponding mechanical features, such as rotator ring 610 and rotator plate 612. The exemplary rotator shown in FIGS. 4A-4B is formed from ring 610 fixed to leg 400a and plate 612 fixed to lateral support 640a. In other embodiments, rotator ring 610 may be fixed to lateral support 640a with rotator plate 612 fixed to leg 400a. Thus, one mechanical feature may be fixed or formed on a first part such as the leg 400a, with a corresponding mechanical feature fixed or formed on a second part such as the lateral support 640a, making the second part (lateral support 640a) rotatable with respect to the first part (leg 400a).

In some embodiments, the footrest 600 may comprise a bottom support 630 rotator 710 (FIGS. 8A-8E). Bottom support rotator 710 may be configured to rotate the bottom support 630 with respect to the lateral supports 640a, 640b. In some embodiments, the rotator 710 may comprise a ring and corresponding plate, as previously described. The ring may be fixed to a respective lateral support 640a, 640b with a rotator plate fixed to bottom support 630. Alternatively, the ring may be fixed to bottom support 630 with a rotator plate fixed to a respective lateral support 640a, 640b.

The rotators 610 and 710 may enable rotation in a single plane, two planes, or three planes. Exemplary rotator 610 is positioned to rotatably connect a respective lateral support 640a to an adjacent leg 400a of the base. A similar rotator (not shown) may be positioned to rotatably connect lateral support 640b to adjacent leg 400b. Exemplary rotator 710 is positioned to rotatably connect a respective lateral support 640b to bottom support 630. A similar rotator (not shown) may be positioned to rotatably connect respective lateral support 640a to bottom support 630.

The footrest 600 may comprise one or more locking mechanism 620. For example, the footrest 600 may comprise one locking mechanism, two locking mechanisms, three locking mechanisms, four locking mechanisms, or more. The locking mechanism 620 may comprise a mechanical or digital feature configured to lock the footrest 600 (for example, the rotator 610) into a desired position for foot support. Locking mechanism 620 may be positioned to correspond with rotator 610 of the footrest 600. In some embodiments, a footrest comprising rotator 710 may comprise a corresponding locking mechanism (not shown) for rotator 710.

In some embodiments, the locking mechanism 620 may lock the footrest 600 in pre-set positions, such as the first position and the second position (e.g., FIGS. 3A-3D). In some embodiments, the locking mechanism 620 may lock the footrest 600 in more than two pre-set positions for foot support, for example, three, four, five, six or more positions for foot support. Five positions for foot support are shown in FIGS. 7A-7E, respectively. Rotators 610 and 710 in each of these five positions are shown in FIGS. 8A-8E. In some embodiments, the locking mechanism 620 may lock the footrest 600 at any desired position along the arc of rotation, for example, any position between the first position (lowest) and the second position (highest). In some embodiments, the locking mechanism 620 may also lock the footrest 600 in a position for storage (for example, a position that is not used for foot support).

One exemplary locking mechanism 620 is formed between locking mechanism peg (denoted 620 in FIG. 4A) and a corresponding locking mechanism slot 622 (FIG. 4B). Locking mechanism peg 620 is positioned on rotator 610. Locking mechanism slot 622 is positioned on rotator plate 612. In use, locking mechanism peg 620 may engage locking mechanism slot 622 to prevent rotation of the footrest 600. Locking mechanism peg 620 may be retractable. Locking mechanism peg 620 may be retracted to disengage locking mechanism slot 622, allowing rotation of footrest 600. The locking mechanism 620 may comprise one or more pegs, for example, two, three, four, five, six or more pegs. In other embodiments, the locking mechanism 620 may have only one peg.

In one exemplary embodiment, locking mechanism 620 includes two pegs 620 and two slots 622. Pegs 620 and slots 622 may correspond to the first position for foot support in a first arrangement, and a second position for foot support when rotated into a second opposite arrangement. However, the locking mechanism may be formed between one peg 620 and two slots 622, each slot 622 associated with a position for foot support. The locking mechanism may comprise more than two pegs 620 and/or more than two slots 622. For additional positions for foot support (for example, more than two positions), the locking mechanism may comprise at least additional slots 622. In some embodiments, at least one slot 622 is provided for each position for foot support.

The footrest 600 may comprise one or more release actuators 650a, 650b. For example, the footrest 600 may comprise one release actuator, two release actuators, three release actuators, four release actuators, or more. Release actuators 650a, 650b may be associated with a corresponding locking mechanism 620. Release actuators 650a, 650b may comprise a mechanical or digital deactivator of the locking mechanism 620. The release actuators 650a, 650b may be configured to release the locking mechanism 620, allowing rotation of the rotator 610. In some embodiments, release actuators may be provided for rotator 710.

In some embodiments, the release actuators 650a, 650b are positioned proximate the locking mechanism 620. Thus, the release actuators 650a, 650b may be positioned proximate corresponding rotator 610. Exemplary release actuators 650a, 650b may be positioned on or adjacent lateral supports 640a, 640b, or accessible from a point on or adjacent lateral supports 640a, 640b, for example, on or adjacent a second end of lateral supports 640a, 640b, at a connection point with corresponding legs 400a, 400b. In some embodiments, release actuators 650a, 650b are positioned on or accessible from a point on legs 400a, 400b proximate lateral supports 640a, 640b. Exemplary release actuators 650a, 650b (FIGS. 3A-3D) are positioned on an internal facing side of a respective leg 400a, 400b.

In other embodiments, release actuators 650a, 650b may be positioned remotely from a corresponding locking mechanism 620 and rotator 610. For example, release actuators 650a, 650b may be positioned on an external facing side of a respective leg 400a, 400b, optionally opposite lateral supports 640a, 640b. Such release actuators 650a, 650b may be operably connected remotely to corresponding locking mechanisms 620a, 620b. Remotely positioned release actuators 650a, 650b may comprise a ramp or other mechanical feature to actuate the locking mechanism 620.

Release actuators 650a, 650b may be in the form of a button, for example, a press button. Actuation of the release actuators 650a, 650b may comprise pressing the button. In some embodiments, the release actuators 650a, 650b may comprise a lever, latch, or slide button. Actuation of the release actuators 650a, 650b may comprise lowering or pulling on the lever, latch, or slide button. In some embodiments, the release actuators 650a, 650b may comprise a screw or knob. Actuation of the release actuators 650a, 650b may comprise twisting the screw or knob. Other release actuators 650a, 650b may be used. In some embodiments, the release actuator 650a, 650b becomes activated (e.g., button pops out or lever is raised or lowered) when the locking mechanism 620a, 620b is enabled, to indicate to a user that the locking mechanism 620a, 620b is properly activated.

The mechanism of one exemplary release actuator 650a is shown in FIG. 5. The release actuator 650a may be operably connected to locking mechanism 620. In the embodiment of FIG. 5, release actuator 650a is mechanically connected to locking mechanism peg 620. In particular, release actuator 650a and locking mechanism peg 620 are formed of a single piece. The release actuator 650a and locking mechanism peg 620 assembly is housed within the rotator 610 housing. The release actuator 650a may be spring-loaded. In use, the compression spring may hold the release actuator 650a in the engaged position (popped up) and locking mechanism peg 620 in the extended or locked position, engaging the corresponding locking mechanism slot 622 and preventing rotation of the rotator plate 612 about rotator 610. Pressing the release actuator 650a button to compress the spring may disengage the release actuator 650a, retracting the locking mechanism peg 620 into the unlocked position. The locking mechanism peg 620 may disengage the corresponding locking mechanism slot 622, allowing rotation of the rotator plate 612 about the rotator ring 610.

In some embodiments, for example, as shown in FIGS. 4A-4B, the lateral support 640a, 640b may comprise an access window for the corresponding release actuator 650a, 650b. When the lateral support 640a, 640b is assembled adjacent the legs 400a, 400b (for example, adjacent the rotator 610), the release actuator 650a, 650b may be accessible via the access window of the lateral support 640a, 640b.

It should be noted that although FIGS. 4A-4B and 5 show rotator plate 612 fixed to lateral support 640a and rotator ring 610 fixed to leg 400a, in some embodiments, the rotator plate 612 may be fixed to leg 400a and rotator ring 610 may be fixed to lateral support 640a. Additionally, release actuator 650a and/or locking mechanism 620 may be fixed to lateral support 640a. Thus, in some embodiments, locking mechanism slot 622 may be positioned on leg 400a.

Exemplary use of the footrest 600 is shown in FIGS. 3A-3D. As shown in FIG. 3A, a user may actuate the release actuators 650a, 650b to enable rotation of the rotator 610. In the second (higher) position shown in FIG. 3A, planar surface 634 is facing up. As shown in FIGS. 3B-3C, the user may drive the footrest 600 to a desired position by rotation of the rotator 610. As shown in FIG. 3D, in the first (lower) position, the planar surface 632 is facing up. The user may actuate the locking mechanism 620 to lock the footrest 600 in the desired position for foot support. The locking mechanism 620 may be automatically enabled when the footrest 600 is rotated into a pre-set position (FIG. 3D). The release actuators 650a, 650b may reset (for example, pop out) to indicate that the locking mechanism 620 is enabled.

In some embodiments, the rotator 610 is configured to rotate in one direction automatically. For example, the rotator 610 may rotate upwards or downwards automatically upon actuation of the release actuators 650a, 650b. Thus, in some embodiments, the rotator 610 may comprise a drive shaft. In some embodiments, the rotator 610 may be allowed to rotate by gravity. The rotator 610 may comprise a damper to reduce motion due to gravity. In other embodiments, the rotator 610 is substantially stationary unless rotation is driven by a user. The rotator 610 may comprise a damper to inhibit motion due to gravity.

In some embodiments, the footrest 600 may provide tactical, visual, and/or auditory feedback to the user indicating motion along the arc of rotation. For instance, the footrest 600 may click or vibrate to indicate motion. The feedback may be provided by a structural feature of the rotator 610. In some embodiments, the feedback may indicate the location of a pre-selected position for foot support or storage. Feedback may be beneficial in embodiments in which the locking mechanism 620 is only able to lock the footrest 600 in a pre-selected position. However, feedback may be provided in embodiments in which the locking mechanism 620 is able to lock the footrest 600 in any position along the arc of rotation.

The highchair may comprise a removable tray table 500. The tray table 500 may be mountable to the seat 100, for example, to one or both arm portions or another structure of the seat. The tray table may be removable. Thus, in some embodiments, the seat 100 may comprise a connection mechanism configured to mate with a corresponding connection mechanism of the tray table 500.

The tray table 500, one or more base (shown as legs 400a-400d), and/or footrest 600 may be formed of a plastic material. Exemplary plastic materials include nylon, acrylic, polypropylene, and polyethylene (such as cross-linked polyethylene (PEX)). Other plastics, such as hard plastics, may be used. In some embodiments, the plastic may be selected to be substantially non-porous for easy cleaning. In some embodiments, the plastic material may be reinforced with a metal core. Exemplary metal materials include aluminum and stainless steel. Other metal reinforcement materials may be used.

The highchair may comprise a harness 200 (FIG. 9). The harness 200 may be designed and positioned to secure the child to the seat 100 in a seated position. The harness 200 may be formed of a flexible or semi-flexible fabric material. Exemplary fabric materials include polyester, nylon, and blends thereof. Other fabric materials may be used. In some embodiments, the fabric material of the harness 200 may be in the form of a mesh, for example, a tightly woven mesh. The harness 200 may include one or more padded strap cushions for comfort.

The harness 200 may have one or more shoulder straps 210, 220 (FIG. 10). Each shoulder strap 210, 220 may be positioned and dimensioned to extend across at least a portion of the torso of the child. Each shoulder strap 210, 220 may extend generally from a point of the backrest above, behind, or in proximity to the shoulder or neck of the child, when seated. The harness 200 may have one or more waist straps, 214, 224 (FIG. 10). The waist strap 214, 224 may be positioned and dimensioned to extend across a waist, lap, or legs of the child. The waist strap 214, 224 may extend generally from a point of the backrest beside, behind, or in proximity to the hip of the child, when seated.

The harness 200 may comprise at least one latch 215, 225 (FIGS. 11A-11B). One or more of a first shoulder strap 210, a second shoulder strap 220, a first waist strap 214, and a second waist strap 224, when present, may comprise a latch 215, 225. The latch 215, 225 may be movable along the strap of the harness 200. The latch 215, 225 may be fixed on the strap of the harness 200.

In some embodiments, the shoulder strap 210, 220 and corresponding waist strap 214, 224 are independent of one another. In other embodiments, the shoulder strap 210, 220 and corresponding waist strap 214, 224 are joined together or formed of the same strap. The shoulder strap 210, 220 and the corresponding waist strap 214, 224 may be joined or come together at a centrally located point of the harness 200, for example, a point of the harness 200 designed to be positioned around the crotch region of the child when the harness 200 is fastened.

In some embodiments, shoulder straps 210 and 220 are independent of one another. In other embodiments, shoulder straps 210 and 220 are joined together or formed of the same strap. The first shoulder strap 210 and the second shoulder strap 220 may be joined or extend behind the head, neck, or back of the child, each shoulder strap emerging from behind the child to extend across a corresponding shoulder of the child, when the child is seated.

In some embodiments, waist straps 214 and 224 are independent of one another. In other embodiments, waist straps 214 and 224 are joined together or formed of the same strap. The first waist strap 214 and the second waist strap 224 may be joined or extend behind the waist, hips, or back of the child, each waist strap emerging from behind the child to extend across a corresponding hip of the child, when the child is seated.

The harness 200 may have one or more crotch straps 230 (FIG. 10). The crotch strap 230 may be positioned to extend between the legs of the child. The crotch strap 230 may have a length selected to extend until a crotch area of the child, when seated. In some embodiments, the crotch strap 230 may comprise a buckle 240. Thus, the harness 200 or highchair may comprise a buckle 240. The buckle 240 may be dimensioned to mate with one or more corresponding latch 215, 225 of the harness 200. The buckle 240 may comprise a latch release mechanism, for example, a button or other mechanical actuator, for releasing the one or more latch 215, 225.

In some embodiments, the harness 200 may be a five-point harness. In a five-point harness, the first and second shoulder strap 210, 220, first and second waist strap 214, 224, and crotch strap 230 may be designed and positioned to meet at a single point. The meeting point of the straps may be at or near a crotch area of the child. The meeting point may be selected to avoid the chest or abdomen of the child. The five-point harness may typically comprise one or more buckles 240 at the meeting point to receive at least one latch 215, 225 securing the straps. In some embodiments, the five-point harness may be formed by two or three straps. One exemplary five-point harness is shown in FIGS. 11A-11B. The exemplary five-point harness is formed by first shoulder strap 210, second shoulder strap 220, and crotch strap 230. As shown in FIGS. 11A-11B, the first shoulder strap 210 and the second shoulder strap 220 may each comprise a corresponding latch, 215, 225. Upon buckling the latch 215, 225 in a centrally positioned buckle 240, the first shoulder strap 210 and second shoulder strap 220 may each form a corresponding shoulder strap portion 212, 222 and a waist strap portion 214, 224, as shown in the buckled view of FIG. 11B. Shoulder strap portions 212, 222 are formed of the same strap and come together at the upper backrest. Waist strap portions 214, 224 join the first shoulder strap portion 212 to the second shoulder strap portion 222 on an opposite end, along the lower backrest. Accordingly, one or two shoulder straps 210, 220 and a crotch strap 230 may form a five-point harness when buckled.

The shoulder strap 210, 220 may be extendable to accommodate a growing child. The seat 100 may have a harness locking mechanism configured to lock the shoulder strap 210, 220 in a desired position, for example, to have a desired length, to accommodate the child. The first shoulder strap 210 and the second shoulder strap 220 may be positioned to come together at the harness locking mechanism. The harness locking mechanism may be fixed to the backrest. The harness locking mechanism may be positioned at a point along the backrest designed to bring the shoulder strap 210, 220 above, behind, or in proximity to the shoulder, neck, or upper back of the child, when seated.

In some embodiments, each of the first shoulder strap 210 and the second shoulder strap 220 is independently extendable and retractable. In other embodiments, each of the first shoulder strap 210 and the second shoulder strap 220 are extendable and retractable together, for example, simultaneously. Thus, in some embodiments, the first shoulder strap 210 and the second shoulder strap 220 may be extended and retracted with a single actuation. The harness locking mechanism may be configured to lock both of the first shoulder strap 210 and the second shoulder strap 220 in the desired position, for example, at the desired length.

The backrest may comprise an aperture on a front side of the backrest. The shoulder strap 210, 220 of the harness 200 may extend through the aperture. In one exemplary embodiment, the aperture may be a through hole of the backrest. Thus, in some embodiments, the slack of the shoulder strap 210, 220 may hang exterior to the seat 100. In some embodiments, the harness locking mechanism may be positioned at the aperture, for example, a housing of the harness locking mechanism may be positioned at the aperture. The housing may substantially cover the aperture.

In certain embodiments, the seat 100 may have an internal chamber. The internal chamber may be positioned within the backrest. In some embodiments, the internal chamber may extend to the bottom surface of the seat. Thus, portions of the seat 100, for example, a portion of the backrest and, optionally, also a portion of the bottom surface, may be hollow. The internal chamber may be accessible through the aperture, for example, positioned beyond the aperture. Thus, in some embodiments, the shoulder strap of the harness 200 may extend through the aperture into the internal chamber. Accordingly, in certain embodiments, the slack of the shoulder strap may be held inside the internal chamber of the seat 100.

In some embodiments, the seat 100 may have at least one lower aperture on a front side of the backrest. The at least one lower aperture may be positioned at a height selected to be proximate to the waist, hips, or lower back of the child when seated. The waist strap 214, 224 may extend through the at least one lower aperture. In one exemplary embodiment, the seat 100 may comprise two lower apertures. The waist strap 214, 224 of the harness 200 may pass through a first lower aperture to the opposite side of the backrest and back through the second lower aperture to the front side of the backrest.

In some embodiments, the seat 100 may comprise an internal channel. The internal channel may have an inlet and an outlet positioned on a front side of the backrest. The inlet may be connected to a first lower aperture of the seat and the outlet may be connected to a second lower aperture of the seat. The waist strap 214, 224 may extend through the internal channel. In some embodiments, the internal channel may be connected to the internal chamber. For example, the first and second lower apertures may open to the internal chamber or a portion of the internal chamber. In other embodiments, the internal channel may be independent from the internal chamber.

The disclosure 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 drawings. The disclosure is capable of other examples and of being practiced or of being carried out in various ways. Also, the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting. The use of “including,” “comprising,” “having,” “containing,” “involving,” and variations thereof herein is meant to encompass the items listed thereafter and equivalents thereof as well as additional terms.

Having thus described several aspects of at least one embodiment of this disclosure, it is to be appreciated that various alterations, modifications, and improvements will readily occur to those skilled in the art. Such alterations, modifications, and improvements are intended to be part of this disclosure and are intended to be within the spirit and scope of the disclosure. Accordingly, the foregoing description and drawings are by way of example only.

HIGHCHAIR FOOTREST

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