There are no applications related to this application.
The present invention is in the general field of reflexive support structures such as mattresses and seating, and more specifically in the field of individual spring components and spring assemblies which are internal to reflexive support structures.
Mattress innersprings, made of matrices or arrays of a plurality of wire form springs or coils, have long been used as the reflexive core of a mattress, which is covered with padding and upholstery to complete a mattress. Innersprings made of formed steel wire are mass produced by machinery which forms the coils from steel wire stock and interconnects or laces the coils together in the matrix array. With such machinery, design attributes of innersprings can be selected and modified, including the gauge of the wire, the coil design or combinations of designs, coil orientation relative to adjacent coils in the matrix array, and the manner of interconnection or lacing of the coils.
There are general design considerations of manufacture and comfort which underlie the design of any mattress. For example, considerable effort has been devoted in the industry to the development of coils with end or terminal convolutions which facilitate the interengagement of the spring coils. For example, end convolutions have been developed having offset portions formed thereon which include a straight portion, such as those disclosed in U.S. Pat. No. 4,726,572 and U.S. Pat. No. 7,404,223. Offset portions enable the spring ends to be secured along a substantial length of the straight portion which will engage with more helical spirals of a lacing wire, and thereby provide more stability for the individual coils. Improved interengagement of the coils of an innerspring without interference and lateral stability is always being sought. Also, ease of manufacture and minimization of costs are always a concern.
An example of a coil which is depicted as having terminal ends which terminate on opposite sides of the coil body is shown in U.S. Pat. No. 7,386,897. As described therein, the coil is used in an innerspring which is constructed with borderwires which encircle the top and bottom support surfaces of the innerspring. As described, the borderwires are necessary for the assembly of an innerspring with this type of coil. The disclosed coils are made of high tensile strength wire to minimize the number of convolutions required to maintain performance characteristics. The high tensile strength wire may minimize the amount of material used but high increases material and handling costs and it also introduces a greater amount of wear on the wire forming equipment.
In one embodiment a reverse coil head coil is described as having a generally helical coil body with a plurality of turns of wire, a first end turn which is contiguous with an upper region of the coil body and lying in a plane which is generally perpendicular to the axis of the coil body, the first end turn being non-helical and a second end turn which is contiguous with a lower region of the coil body and lying in a plane which is generally perpendicular to the axis of the coil body, the second end turn being non-helical. A connecting segment is located between the first end turn and the coil body in the form of a gradient arm extending in the same plane as the terminal convolution. The first and second end turns each have a free end, both free ends being located on the same side of the axis of the coil body.
In another embodiment the reverse coil head coil is described as having a generally cylindrical body with three or more helical turns of wire which form a helical path about a longitudinal axis of the coil, the coil body terminating at opposed axial ends, each of the opposed axial ends having an offset and a free end, the free ends terminating on the same side of the longitudinal axis of the coil. The pitch and diameter of a helical turn located at the center of the coil body is less than the pitch and diameter of the other helical turns. A gradient arm is located between one of the opposed axial ends of the coil body and the coil body.
In another embodiment, a mattress innerspring is described comprising a plurality of wire coils interconnected in an array, each wire coil comprising a coil body with a terminal convolution at opposing ends and a plurality of convolutions therebetween, each terminal convolution being in a plane which is generally perpendicular to a longitudinal axis of the coil body and having a free end and at least one linear segment. A gradient arm is located between one terminal convolution and one of the plurality of convolutions. The free or terminal ends of the ends of the coil are on the same side of the coil body. Although this coil design works well in practice when laced together in an innerspring, because the terminal wire ends of the coil ends are one the same side of the coil body or axially aligned, each coil has a tendency or bias to lean toward the terminal ends when compressed. This bias is magnified in an innerspring made with these coils giving the innerspring a tendency to lean, which must be controlled or countered with the surrounding components of the mattress construction.
As shown in the Figures, a reverse coil head coil (hereinafter referred to as “RCH coil” or “coil”) of the present disclosure and related inventions is indicated in its entirety at reference numeral 10. The RCH coil 10 has a generally helical and cylindrical body 12c formed by a plurality of generally helical turns, such as 20a, 20b and 20c. The coil body 12c is connected to respective coil ends 12a, 12b. The coil ends 12a, 12b can be in any form, and have one or more segments which are generally in the same plane and generally perpendicular to an axis of the coil body. In the embodiment shown in
The coil body 12c has a longitudinal axis which runs the length of the coil at the radial center of each of the helical turns of the coil. The coil body is contiguous with a first coil end, generally indicated at 12a, and a second coil end, generally indicated at 12b. The designations “first coil end” and “second coil end” are for identification and reference only and do not otherwise define the locations or orientations of the coil ends. Accordingly, either the first coil end 12a or the second coil end 12b may alternatively be referred to herein as a “coil end”. Either of the coil ends 12a, 12b may serve as the support end of the coil in an innerspring in a one-sided or two-sided mattress. The two coil ends 12a, 12b do not have to be identically configured. The coil ends 12a, 12b lie generally in respective planes generally perpendicular to the longitudinal axis of the coil body and form the generally planar support or bottom surfaces of an innerspring. The coil, ends 12a, 12b can be of identical form or dissimilar forms and may have a generally larger diameter than the coil body or extend laterally beyond the coil body.
The coil ends 12a, 12b are each formed in an open end offset configuration that includes three offset portions and an open or terminal end. Terminal ends 15a and 15b (also referred to herein as “free ends”) are left open with respect to the coil, that is they do not return to the coil body or coil end and are not tied or knotted thereto. As shown in
The first offset 13 extends from a transition or connecting segment 16 which connects the coil ends 12a, 12b to the coil body 12c. The integral connection of the connecting segment 16 and the coil body 12c is at a transition angle from the helical coil body 12c which forms a gradient arm 16a, in the general region indicated, which alters the spring rate of the coil under different types of loads. The compression of the coil, and thus the firmness of the coil, can be adjusted within limits by varying the length and angle of the gradient arm 16a relative to the coil body 12c and coil end 12a, 12b. The gradient arm 16 adds extra support when a load is applied to the coil, as described in U.S. Pat. No. 4,726,572, which is incorporated herein by reference.
A preferred embodiment of the RCH coils of the present disclosure is made from a single piece of wire which is first given a spiral shape and then formed with the desired coil ends or terminal convolutions. In a preferred embodiment, the wire stock is for example, such as 14.25 gauge wire with a tensile strength between 235,000 and 255,000 psi. The coil has an approximate overall axial length in a range of about 6.0 inches to 6.5 inches with approximately 4.75 turns or revolutions. The center convolution 20b has a slightly smaller pitch and diameter measurements than the two convolutions 20a, 20c adjacent to center. The center convolution 20b has both a pitch and a diameter of approximately 44 mm. The two convolutions 20a, 20c adjacent to the center convolution each have a pitch and diameter of approximately 48 mm. The approximate length of each free end 15b is approximately 15 mm.
It will be appreciated by persons skilled in the art that numerous variations and/or modifications may be made to the invention as shown in the specific embodiments without departing from the spirit or scope of the invention as broadly described. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive. Other features and aspects of this invention will be appreciated by those skilled in the art upon reading and comprehending this disclosure. Such features, aspects, and expected variations and modifications of the reported results and examples are clearly within the scope of the invention where the invention is limited solely by the scope of the following claims.