1. Field of the Invention
The present invention relates generally to folding chairs. More particularly, the present invention relates to a mesh folding chair.
2. Related Art
Folding chairs are often used in situations in which it is desirable or necessary to provide varying numbers and/or varying layouts of chairs, such as during conventions, seminars, conferences, etc. In addition, folding chairs are often used in multipurpose areas in which patron seating is required for some functions, but a large open space is required for other functions necessitating storage of the chairs. For example, some organizations have buildings with a multipurpose room which may be used for banquets, seminars, conventions, etc., with chairs set up, or for a dance, sporting event, etc., with the folding chairs removed. Furthermore, folding chairs are often used domestically/residentially to accommodate larger dinner-parties or the like.
It is desirable that the folding chairs be capable of being folded and stacked for storage so that the chairs take up less room when they are not required. It will be appreciated that some situations or events will require thousands of folding chairs, all of which may need to be folded and stored at any given period. Thus, the chairs must be folded and stored such that they have a high storage density to minimize the storage space required. It will be appreciated that any extra thickness of a chair when folded becomes significant when numerous folding chairs are involved. For example, with a thousand stacked folding chairs, a folding chair which saves one extra inch in the folded position results in over 80 linear feet of saved storage space. In addition, it will be appreciated that numerous stacked chairs can be difficult to handle or store, and may separate from one another. Furthermore, it will be appreciated that chairs can be unsymmetrical so that stacking several chairs together results in a non-linear stack which can lead to separation.
One disadvantage with many prior art folding chairs is the bulk or thickness of the chair in the folded position. Many typical folding chairs still remain several inches thick in the folded position, and thus are less dense when stored. For example, many typical folding chairs have seats which fold adjacent to or abut the legs, such that the thickness of the chairs in the folded position comprises the thickness of the legs and the seat.
In addition, it is desirable that the folding chairs be easily storable or stackable, and be stable when stored/stacked. Many typical prior art folding chairs are stored merely by leaning one chair against a wall and subsequent chairs in a series against the first chair. It will be appreciated that a plurality of folding chairs stacked against a wall has a potential domino effect, with all of the chairs subject to being knocked over. Other prior art folding chairs have complicated and expensive hanging rack systems. For example, a wheeled cart might have a plurality of support arms from which a plurality of folding chairs is suspended. One disadvantage of these types of systems is that chairs on the end of the hangers tend to fall off the rack, and the wheeled racks are difficult to move and maneuver.
It also is desirable that the chairs be comfortable. Typical prior art folding chairs have rigid metal seats and seat backs which can be hard and uncomfortable. One disadvantage of many prior art folding chairs is that the chairs either fold well and are uncomfortable, or are comfortable but are awkward in folding. Thus, there tends to be a trade off between comfort and foldability. Some chairs provide a cushion. But these chairs still utilize the rigid metal seat bottoms and seat backs, and the cushions tend to make the chairs even thicker when folded. For example, see U.S. Pat. No. 2,877,829 and D357,365.
Other types of chairs, such as office chairs, have been design for greater comfort and aesthetic appearance, but which do not fold or stack. For example, see U.S. Pat. Nos. 6,125,521 and 7,249,802.
It has been recognized that it would be advantageous to develop a folding chair with greater comfort while maintaining high density storage. In addition, it has been recognized that it would be advantageous to develop a chair utilizing a mesh seating surface for comfort and space saving in a folding chair. In addition, it has been recognized that it would be advantageous to develop a chair utilizing the comfort of a mesh seating surface in a folding and stacking chair. In addition, it has been recognized that it would be advantageous to develop such a folding and stacking chair with a mesh seating surface that is both economically viable and structurally sound.
The invention provides a folding chair including a seat and a backrest carried between opposite frame sides each with a backrest support, a front leg and a rear leg. In an unfolded seating position, the seat pivots to extend from the frame sides and bottoms of the front and rear legs move apart. In a folded position, the seat pivots toward the frame sides and the front and rear legs move together. One or both of the seat and the backrest have a continuous sheet of flexible and elastic mesh or patterned open texture plastic held across and substantially covering an opening in an all-plastic hoop fixed between the frame sides. The hoop includes inner and outer plastic mating hoops with the mesh extending over an outer perimeter of the inner hoop and into an interface between the inner and outer hoops.
In accordance with a more detailed aspect of the present invention, the all-plastic hoop of the backrest and the all-plastic hoop of the seat form the sole structural support between the frame sides above a bottom of the frame sides.
Additional features and advantages of the invention will be apparent from the detailed description which follows, taken in conjunction with the accompanying drawings, which together illustrate, by way of example, features of the invention; and, wherein:
a is a side view of a folding and stacking chair system in accordance with an embodiment of the present invention with a plurality of folding and stacking chairs of
b is a partial side view of the folding and stacking chair system of
c is a partial cross-section view taken along line 14c of the folding and stacking chair system of
d is a partial side view of the folding and stacking chair system of
e is a partial cross-section view taken along line 14e of the folding and stacking chair system of
a is a perspective view of a foot in accordance with an embodiment of the present invention of the mesh folding chair of
b is a partial perspective view of the mesh folding chair of
c is a top view of the foot of
a is perspective view of a top stop in accordance with an embodiment of the present invention of the mesh folding chair of
b is a side view of the top stop of
c is a perspective view of the top stop of
a is a partial perspective view of the mesh folding chair of
b is a partial bottom cross-sectional view taken along line 17b of the mesh folding chair of
a is a partial front view of a backrest in accordance with an embodiment of the present invention of the mesh folding chair of
b is a partial cross-sectional view taken along line 18b of the mesh folding chair of
c is a side view of the backrest of
d is a partial cross-sectional view taken along line 18d of the backrest of
a is a cross-sectional side view of another mesh folding chair in accordance with another embodiment of the present invention;
b is a side view of a seat of the mesh folding chair of
c is a perspective view of the seat of
d is a bottom view of the seat of
e is a top view of the seat of
f is a partial rear view of the mesh folding chair of
g is a partial cross sectional view of a backrest of the mesh folding chair of
a is a perspective view of a mesh folding chair in accordance with another embodiment of the present invention shown with a pivoting seat in an unfolded seating position and with mesh of the seat and backrest mostly removed for clarity; and
b is a perspective view of the mesh folding chair of
Reference will now be made to the exemplary embodiments illustrated, and specific language will be used herein to describe the same. It will nevertheless be understood that no limitation of the scope of the invention is thereby intended.
As illustrated in
The chair 10 can include a frame with opposite frame sides 22a and 22b that carry the seat and backrest therebetween. The frame sides can each include an elongated member defining a front leg 26a and 26b with a lower portion thereof, and a backrest support 30a and 30b with an upper portion thereof. Thus, the backrest support 30a and 30b is essentially an extension of the front leg 26 and 26b. In addition, the opposite side frames can each include a rear leg 34a and 34b. The frame sides 22a and 22b can be coupled together by the seat 14 and backrest 18, and by front and rear lower cross members 38 and 40 that extend between the front and rear legs respectively nearer a lower end of the legs. The front and rear legs are pivotally or movably coupled together, and pivot or move with respect to one another. The front and rear legs can be coupled together by the seat 14 and a link 44a and 44b. Thus, the seat 14 is pivotally coupled to both the front and rear legs. Similarly, the link 44a and 44b is pivotally coupled to both the front and rear legs. The front and rear legs and the backrest support can be formed of metal, such as steel or aluminum, and can be tubular for lighter weight. The cross-sectional shape of the members and chair legs can be elliptical for added strength. In addition, the members can be curvilinear and can have a stretched s-shaped profile to facilitate stacking. The front and rear legs can have matching curvature so that they can nest adjacent one another. The chair 10 can have an unfolded seating position, as shown in
The seat 14 and the backrest 18 can each have a continuous sheet of flexible and elastic mesh (represented by 44 in
Alternatively, the seat 14 and the backrest 18 can each have a continuous sheet of flexible and elastic patterned open texture plastic (represented by 46 in
In either case, the sheet of mesh or the sheet of plastic can provide the sole or only support of the user's weight. Thus, each side of the sheet of mesh or the sheet of plastic can be free or open, without other materials or fillers, such as foam or cloth.
In one aspect, only the seat can include the mesh supported by a seat frame. In another aspect, only the backrest can include the mesh supported between the backrest supports of the frame sides or a backrest frame. In another aspect, both the seat and the backrest can include the mesh. Whether one of the seat or the backrest or both include mesh can depend on the needs of the user. In addition, the sheet of mesh 44 can be held taut across and substantially cover an opening in an all-plastic hoop 48 fixed between the frame sides. For example, the seat can include an all-plastic seat hoop 52 and the backrest can include an all-plastic backrest hoop 56. The resiliency in the seat and backrest can be suited to the user's preference. In one aspect, the mesh of the seat can be stretched 4.5 to 5%, while the mesh of the backrest can be stretched 2.7 to 3.2%. Thus the backrest can have greater deflection and a softer feel because the loading on the backrest is not as great as the seat. In addition, the mesh can have variable tension along a longitudinal direction (front to back for the seat or top to bottom for the backrest) to provide for great comfort. The degree of lateral tension of the mesh of the backrest can vary along the height or elevation of the backrest to create lumbar support at a desired location. The mesh suspended between the hoops can provide greater comfort than traditional solid plastic or solid metal chairs while maintaining stackability and high density storage of folding chairs. Similarly, the mesh can have variable lateral (side-to-side) tension. The all-plastic hoops can be formed by injection molding plastic, and may be formed of, or can include, polypropylene or nylon or ABS. In one aspect, the hoops can be formed of nylon and the seat hoop 52 can weigh less than 2.5 lbs, the backrest hoop 56 can weigh less than 1.5 lbs, and together can weigh less than 4 lbs, to reduce the weight of the chair while providing sufficient strength. In another aspect, the hoops can be formed of nylon and the seat hoop can weigh less than 2 lbs, the backrest hoop can weigh less than 1 lbs, and together can weigh less than 3 lbs. In another aspect, the hoops can be formed of polypropylene and the seat hoop can weigh less than 2 lbs, the backrest hoop can weigh less than 1 lbs, and together can weigh less than 3 lbs. In another aspect, the hoops can be formed of polypropylene and the seat hoop can weigh less than 1.6 lbs, the backrest hoop can weigh less than 0.8 lbs, and together can weigh less than 2.4 lbs. The amount or weight of the plastic material of the all-plastic hoops is balance to provide sufficient strength to the frame and the sheet of mesh or plastic, while also reducing the weight of the chair. Such a configuration as described above can support a static load of at least 1250 lbs. In another aspect, it is believed that sufficient strength can be provided by a seat hoop with a weight as low as 1.25 lbs, a backrest hoop with a weight as low as 0.5 lbs, and a combined weight as low as 1.75. The all-plastic hoops are all-plastic in that they do not have any internal or external metal reinforcement members, although the plastic of the hoops can have fillers such as glass fibers. Thus, the seat and/or backrest hoops support both the mesh and the frame, reducing the number of parts and cost of the chair. The mesh 44 can be bonded, such as chemically or adhesively, in a channel 60 (
The mesh 44 of the seat 14 and backrest 18 held taut in the hoops provide the comfort of an upholstered comfort in a non-upholstered folding chair; while the hoops 48 can provide the sole, or only, structural support between the frame sides above the bottom thereof, or above the front and rear lower cross members 38 and 40. As described above, the hoops can provide the support for both the mesh and the frame sides of the folding chair. The all-plastic hoop 56 of the backrest provides the sole structural support between the backrest supports 30a and 30b of the frame sides 22a and 22b. Similarly, the all-plastic hoop 52 of the seat provides the sole structural support between the frame sides 22a and 22b at a middle of the chair or frame sides. Together, the all-plastic hoops 52 and 56 of the seat and backrest provide the sole structural support between the frame sides 22a and 22b above the bottom of the frame where the lower cross members 38 and 40 are located. The hoops can be directly coupled to the frame sides, without intervening support members. The seat hoop 52 can be coupled to the frame sides, or front and rear legs, by rivets which also form pivot points. The backrest hoop 56 can couple to the backrest supports as described below. The hoops can be injection molded nylon with a total weight of less than 3 lbs to provide both light weight for ease of folding and unfolding and moving the chairs, and strength to support the taut mesh across the opening and support the frame sides.
The seat 14 and/or seat hoop 52 can be sized and shaped for both comfort and structural support. The seat hoop 52 can have opposite, parallel, substantially straight, hoop sides 64a and 64b coupled to the frame sides. A front 68 extends between the hoop sides and the front and/or front ends of the frame sides can arc downward (with respect to the chair in the unfolded seating position), or form an arc. The sheet of mesh 44 held taut between the seat hoop forms a longitudinal convex arc (represented at 72) at the front defining a leg relief near the front of the hoop of the seat. The mesh arc 72 or thigh support can have a broad downward curvature to provide comfort to the user's thighs when seated. The seat hoop 52 can have a substantially square shape with rounded corners. The front 68 of the seat hoop 52 can curve forwardly out of the square shape and downwardly out of the plane of the square.
An upper surface 74, or majority thereof, of the seat is oriented at an incline with respect to horizontal in the unfolded seating position, as shown in
The seat hoop 52 can also include a rigid plastic seat-support bar 76 laterally traversing the seat hoop to provide support to the seat hoop and frame sides. As a user sits on the mesh 44 of the seat 14, the mesh pulls inwardly on the seat hoop 52, and thus the frame sides 22a and 22b; which is resisted by the seat-support bar 76. The bar has an arcuate shape that curves downwardly from the sides to the center and into which the mesh of the seat can deflect when a user sits on the seat. Each side of the bar 76 can have a pair of vertical, parallel, spaced-apart flanges 80 (
As described above, the all-plastic seat hoop 52 can be directly coupled to the frame sides 22a and 22b without external support members. A pair of lobes 84a and 84b can extend downwardly from lateral sides of the seat hoop 52 in the unfolded seating position. Each frame side 22a and 22b, or front and rear legs, can be pivotally coupled to a different one of the lobes 84a and 84b respectively. The lobes can be formed by plastic along with the chair hoop. Integral plastic spacers 88 (
The seat 14 and/or seat hoop 52 forms a four-bar, four-pivot linkage on each side along with the front leg 26a and 26b, the rear leg 34a and 34b, and the link 44a and 44b. As described above, the seat hoop 52 is all-plastic. The front and rear legs, and the links, can be non-plastic, such as steel or aluminum. Thus, the seat and/or seat hoop forms a single all-plastic link in the four-bar linkage. The front legs 26a and 26b and backrest supports 30a and 30b can be formed of at least 16 gauge steel with an oval or elongated tubular cross section. The rear legs 34a and 34b can be formed of at least 18 gauge steel also an oval or elongated tubular cross section. The rivets 100 can be at least 5/16″. It is believed that the above described configuration provides a sufficient balance of weight savings and strength.
The backrest 18 and/or backrest hoop 56 can be sized and shaped for both comfort and structural support. The backrest hoop 56 can have opposite, parallel, substantially straight, hoop sides 104a and 104b coupled to the backrest supports 30a and 30b of the frame sides. A top 108 extends between the top ends of the hoop sides. The top can have an upward curvature. An arcuate bottom 112 extends between bottom ends of the hoop sides. The bottom arcs rearward with respect to the chair and to a greater degree than any arcing of the top in the rearward direction. The bottom of the backrest forms a deeper arc than a top of the backrest. The sheet of mesh 44 forms a lumbar support near the arcuate bottom of the hoop of the backrest. The sheet of mesh 44 stretched taut between the backrest hoop forms an upright convex arc (represented at 116) between the top and the bottom, and a lateral concave arc (represented at 120) between the hoop sides. The backrest hoop 56 can have a substantially square shape with rounded corners. The top 108 of the backrest hoop 56 can curve outwardly out of the square shape in the plane of the square, while the bottom 112 can curve outwardly out the plane of the square.
The all-plastic backrest hoop 56 can be directly coupled to the backrest supports 30a and 30b of the frame sides 22a and 22b. As described above, the backrest supports of the frame sides can have a tubular configuration with an open top end. The open top ends can be oriented orthogonal to the tube and can form a flat annular opening. The backrest hoop 56 has a pair of shoulders that extend from the hoop and over the open top ends of the backrest supports to cover the openings. In addition, the backrest hoop includes a pair of opposite side fingers 124 (
Referring to
Referring to
Referring to
The top stop or bottom of the support channel 182 has an unfolded, support abutment surface 190 (
The top stop or bottom of the stacking channel 186 has a folded, stacking abutment surface 202 (
The top stops can have an insert portion for insertion into the open upper end of the rear legs and forming an interference fit. In addition, the top stops can have a rivet hook 214 extending into the rear legs and around a rivet through the rear legs. The top stops can be formed of plastic. The plastic can be flexible to flex and snap around the rivet during assembly. The plastic can include a harder plastic body 218 with a softer plastic 222 disposed over the body, such as on the abutment surface or fins to resist injury to pinched fingers and/or to reduce noise, as shown in
Referring again to
When several chairs are stacked and horizontally oriented, a greater portion of the weight or mass of the chairs is located towards the bottom of the chair (or to a lateral side when stacked). This weight keeps the bottom portion of halves of the chairs together when stacked, and keeps the upper portion or halves of the chairs separated from one another, so that the chairs maintain an aligned vertical stack.
The aspects of the chair described above help provide an improved stacking chair; with decreased weight while retaining strength and comfort; while maintaining an affordable and manufacturable chair. The curvilinear profile of the frame and chair legs in the folded configuration and the alignment channels of the top stops and the feet combine to provide a stable and stackable chair. In addition, the mesh stretched between plastic hoops provides comfort and reduces weight while maintaining strength and affordability.
As described above, the seat and the backrest, or the hoops thereof, can be injection molded. The mesh can be secured between the mating hoops and the hoops attached. The seat can be pivotally coupled to the elongated members and rear chair legs, such as with rivets. The backrest can be slid into engagement with the elongated members, and self-locking by the finger.
Referring to
The pair of mating annular hoops of the seat can include mating annular notches. The mating notches can trap or sandwich the mesh material. The bottom hoop can include an annular notch formed around a top inner perimeter. The top hoop can be received within the annular notch. The top hoop can have an annular flange formed around a bottom inner perimeter and extending within an inner perimeter of the bottom hoop. In addition, the top hoop can have an upper surface 316 that is curved and inclined inwardly for comfort. The mesh material can extend over the top or upper surface of the top hoop and between the hoops. The hoops can be attached by mechanical fasteners, such as screws or staples. In addition, the hoops can be joined by adhesive, sonic welding, etc.
The outer hoop 300 of the seat includes lateral hooks 320 (
Alternatively, the inner hoop of either the seat or the backrest can have a projection or flange, such as an annular flange, that extends into a channel or groove of the outer hoop, such as a mating annular channel, so that force applied to the inner hoop it transferred to the outer hoop through the mating projection and channel to reduce stress on any fasteners. Alternatively, the projection can be formed on the outer hoop and the channel can be formed on the inner hoop.
Referring to
The outer hoop 300 of the seat 14b includes an interior projecting flange 332. A plurality of cut-outs 336 can be formed in the flange to reduce weight.
Referring to
Although one frame or folding configuration has been described above and shown in the drawings, it will be appreciated that other frame and folding configurations can be used with the mesh seat and/or mesh backrest of the present invention.
While the forgoing examples are illustrative of the principles of the present invention in one or more particular applications, it will be apparent to those of ordinary skill in the art that numerous modifications in form, usage and details of implementation can be made without the exercise of inventive faculty, and without departing from the principles and concepts of the invention. Accordingly, it is not intended that the invention be limited, except as by the claims set forth below.
Priority of U.S. Provisional Patent Application Ser. No. 61/140,756, filed on Dec. 24, 2008, is claimed; and is hereby incorporated herein by reference in its entirety. This is related to U.S. Design application Ser. No. 29/335,295 filed Apr. 13, 2009; U.S. patent application Ser. No. 12/422,792, filed Apr. 13, 2009, entitled “Mesh Folding Chair”; U.S. patent application Ser. No. 12/422,801, filed Apr. 13, 2009, entitled “Comfortable Mesh Folding Chair”; U.S. patent application Ser. No. 12/422,811, filed Apr. 13, 2009, entitled “Folding and Stacking Mesh Chair System”; all of which are incorporated herein by reference in their entirety.
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