UNITS Cross Reference To Related Applications This application is a continuation-in-part application of

parent application U.S. Serial No. 08/406,694 entitled Mattress

Innerspring Structure Having Coaxial Coil Units, filed March 20, 1995, which parent application is incorporated herein by reference in its entirety.

Field of the Invention

This invention relates generally to mattress innerspring structures and specifically to an innerspring structure having sections of enhanced firmness. Background of the Invention

Conventionally, mattress innerspring structures comprise a plurality of coil springs or coils which are positioned

adjacent one another to extend between top and bottom face

surfaces of a mattress. The coils are usually arranged in rows which determine the length and width of the innerspring structure. When individual coil springs or coils are used, they are held together by various means to form a unitary innerspring structure.

Alternatively, a row of coils may be formed from a single continuous piece of wire wherein each of the single coils are connected in the row by interconnecting segments. The rows are then fixed together to form the innerspring structure. Examples of

such spring assemblies having rows formed of a continuous piece of wire are disclosed in U.S Patent Nos. 4,358,097 and 4,488,712 which are commonly owned with the present application.

The coils in the innerspring structure are typically formed very similar to each other, having generally the same coil

diameter and similar stiffness, as dictated by the gauge of wire used to make the coils and the number of turns or pitch of each coil. Therefore, the top surface of a typical mattress will have generally equal firmness throughout the length and width of the

mattress made from such an innerspring structure. However, it is often desirable to make certain areas on

the mattress more firm than other areas of the mattress. For

example, it may be desirable to firm up the center section of the mattress which receives a majority of the weight from a person

lying thereon. Further, it may be desirable to make the edge of a

mattress more firm or durable to withstand pressures created when

a person sits on the end of their bed.

Varying the stiffness of individual coils, such as by

using different wire gauges and/or different numbers of coil turns, it might be possible to change the firmness in certain areas of an innerspring. However, as may be appreciated, such an undertaking

would require constant conversion of the coil forming machine, and

thus would result in a substantial cost increase attributable to both labor for the machine conversion and the delay in forming the

innerspring structures. Furthermore, the availability of various different wire materials and gauges for forming different coils for a

single innerspring structure would have to be coordinated.

Therefore, such an approach is impractical from a cost standpoint. It is also desirable to vary the firmness in certain areas of an innerspring structure which utilizes continuous coil spring units. Such continuous coil spring products have met with considerable commercial success, primarily because considerably

less material is required for the same degree of firmness in such a

spring product than has been employed in spring assemblies which utilize rows of interconnected individual coil springs. However, the spring products made from these continuous coil springs have been found to be difficult or very expensive to modify in order to obtain

sections of the product which are more firm than other sections of the same spring product. Varying the wire gauge or coil turns of a

particular coil or coils in the product is not a practical option, because all coils are formed of a continuous piece of wire.

Furthermore, breaking a particular continuous row of coils into discontinuous sections would destroy many of the benefits of the continuous coil spring product. Therefore, it is an objective of the present invention to increase the firmness in selected areas of a mattress.

It is a further objective to increase the durability of

selected areas on a mattress which receive a high amount of loading during normal usage.

Accordingly, it is another objective of the invention to provide an innerspring structure which is more firm and provides

greater support in certain areas thereon than in other areas.

Furthermore, it is an objective of the invention to provide such an innerspring structure at a relatively low cost and

with a relatively uncomplicated design.

It is another objective of the invention to create a

continuous coil spring product which is so constructed that various sections of the product have varied degrees of firmness.

It is still another objective to provide a continuous coil spring product and a method for constructing same which will not

require substantial variations in the assembly process in order to form sections of the product with varying firmness.

Summary of the Invention

In accordance with the above-stated objectives, an

innerspring structure utilizes reinforced coil units having a coil within a coil design constructed to form coaxial coil units. The

coaxial coil units are coupled together into a unitary innerspring structure by helical lacing wire.

In one embodiment, the innerspring structure comprises a plurality of individual, side-by-side coils, referred to

herein as outer coils, which extend generally parallel to one another and are arranged in aligned rows. The outer coils have opposing end turns which collectively form top and bottom face surfaces of

the innerspring structure. Selected rows or selected areas of the innerspring structure further comprise one or more individual inner coils which extend between the top and bottom face surfaces of the structure. The inner coils are each wound and positioned

generally coaxially within a respective outer coil, such that the end turns of the inner and outer coils are adjacent each other. The

inner and outer coils form generally coaxial coil units. A matrix of helical lacing wires connects the inner and outer coils together at

the end turns to form a reinforced generally coaxial coil unit, having a coil within a coil. The reinforced coil units have enhanced firmness or stiffness relative to just the unitary outer coils or just the inner coils. Preferably, the inner and outer coils are just pushed or positioned together from the sides thereof to form the coaxial units. Accordingly, the terms "inner" and "outer" are used primarily for reference and do not necessarily indicate the overall orientations of the coils within the coaxial spring unit.

The lacing matrix also connects the aligned rows of coils together. The lacing matrix includes a plurality of spaced apart helical wires which extend generally parallel one another and

generally perpendicular to the aligned rows. Each wire wraps

together the end turns of adjacent coils such that each coil within a

row is connected to an adjacent coil in that row. The rows of

reinforced coil units and rows of unitary outer coils are connected

together to form a unitary innerspring structure. Another helical

wire is wound around the periphery of the innerspring structure to

connect peripheral coils to a thick border wire for enhanced edge

firmness in the innerspring structure. The rows or areas of the

innerspring structure, which include the coaxial units of inner coils

within outer coils, create an area on the structure having a

stiffness or firmness which is higher than those areas which only

utilize unitary outer coils.

In one embodiment of the invention, each coil unit

within a selected row or rows of coils utilizes an inner coil within

an outer coil, such that reinforced rows of coaxial coil units are

produced. Alternatively, only one or a selected number of units

within a particular row might be the reinforced coaxial unit having a

coil within a coil design. Similarly, all of the peripheral coils

coupled to the border wire might be reinforced coaxial coil units to

strengthen the sides of the innerspring structure. The respective

inner and outer coils of a reinforced coil unit preferably have the

same pitch and the same winding direction, i.e., left hand or right

hand winding. Furthermore, the coils are formed such that the end

turns and intermediate turns of each of the inner and outer coils

have the same diameter. As such, the inner and outer coils

preferably have a similar shape and nest together to form a coil unit

with a double wire thickness to provide the desired firmness in

selected areas of the mattress. The coils, including any inventive

coaxial coil units, are positioned together and laced together. Since

the inner and outer coils are generally co-extensive in each coaxial

unit, the coaxial unit has generally equal support strength or

firmness along its length.

An alternative embodiment of the invention utilizes a

continuous coil spring product positioned with a similar continuous

coil spring product such that the two products interact and form a

row of adjacent coaxial coil units which generally have an inner coil

with an outer coil. Each row generally consists of a plurality

adjacent coil pairs which are interconnected by a Z-shaped wire

segments positioned proximate the top and bottom planes of the

coil rows and staggered such that each coil is connected to an

adjacent coil either proximate the top plane or the bottom plane.

When individual rows of continuous coil springs are positioned

adjacent each other to form an innerspring structure, the various Z-

shaped interconnecting segments are aligned both in rows and in columns in the top and bottom planes of the innerspring structure.

To form the coaxial coil units of the present invention, a row of outer coils, formed from a continuous piece of wire, is

positioned as a row of the innerspring structure. A row of inner

coils, also formed from a continuous piece of wire, is then positioned generally parallel to the row of outer coils such that the various inner and outer coils intermesh and the respective Z-shaped

interconnecting segments are aligned and generally overlapped to form the reinforced coaxial coil units of the invention. As referenced above, the designations of "inner" and "outer" are utilized for reference and do not imply that one set of coils has turns with larger diameters than another set of coils or that the inner set of coils fits completely within the outer set of coils. Preferably, the coil units in the row of outer coils have the same number of turns (pitch) and turn diameters as the coil units in the row of inner coils such that they would generally be interchangeable. To form the coaxial coil units, a row of outer coils is positioned generally parallel to a row of inner coils. The coil rows are then moved together and intermeshed to form a row of

coaxial coil units in accordance with the principles of the invention,

similar to the way in which individual coils might be positioned

together; however, entire rows are intermeshed simultaneously.

In order to form an innerspring structure having

particular areas of varying firmness, the rows of coaxial coils are

positioned in the particular area of the innerspring structure.

Preferably, the rows extend transversely on the innerspring

structure. Additional single continuous rows of coils are then

positioned on either side of the rows of coaxial units, as

appropriate, to form the remainder of the innerspring structure.

The Z-shaped segments of the various adjacent rows of single coils

and coaxial coils which interconnected adjacent pairs of coils or

pairs of coaxial coil units within each row are positioned so that

they overlap. The overlapped portions or sections of the Z-shaped

segments are then tied together by helical wire connectors.

A first set of helical wire connectors will be disposed

within the top plane of the upper innerspring surface so as to join

together overlap portions of upper Z-shaped interconnection

segments. Similarly, a second set of helical wire connectors lie

within the bottom plane of the innerspring surface and join together

overlapped portions of lower Z-shaped interconnection segments.

The length of each helical wire is approximately the same as the

length of the connected rows, which preferably defines the width

of the innerspring structure. In accordance with the principles of the invention, the rows might also be longitudinal rows if it is

desirable to firm up various sections of the innerspring structure in

the longitudinal direction as opposed to the transverse direction.

The helical wire connectors connect together overlapping Z-shaped interconnection segments of the inner and

outer coils to form the coaxial coil units. The helical wires also connect together the various adjacent rows to form the innerspring structure. Once the various rows of reinforced coaxial coil units

are constructed, and adjacent rows are secured together, the entire innerspring structure may be secured around its perimeter to a

border wire utilizing another helical wire connector as part of the lacing matrix for the innerspring structure. Therefore, the innerspring structure of the present invention provides the desired increased firmness and durability for selected areas of the mattress utilizing reinforced coil units having coils within coils laced by helical lacing wire. The inner and outer

coils utilized to form the reinforced coil unit are preferably similar and therefore, the complexity of manufacturing the innerspring

structure is not drastically increased over the process used to make

a conventional innerspring structure which has the same firmness

throughout. Furthermore, no special wire or coiling techniques are

necessary for creating the reinforced coil units, thereby keeping

manufacturing costs to a minimum. The inner and outer coils are

positioned together to form the coaxial units. The present

invention further presents an innerspring structure utilizing

continuous coil spring units in combination with rows of coaxial coil

units for varying the firmness characteristics of the innerspring

while maintaining the desirable characteristics of the continuous

coil spring product.

The above and other objects and advantages of the

present invention shall be made apparent from the accompanying

drawings and the description thereof.

Brief Description of the Drawing

Fig. 1 is a top view of the innerspring structure of the

present invention utilizing reinforced coil units laced together by a

helical wire matrix;

Fig. 2 is cross-sectional view taken on lines 2-2 of the

innerspring structure of Fig. 1 ;

Fig. 3 is a cross-sectional view along lines 3-3 of Fig. 1 illustrating a reinforced coil unit of the invention helically laced to

a border wire;

Fig. 4A is a perspective view of a continuous coil

spring product having coaxial coil units in accordance with the principles of the invention;

Fig. 4B is a perspective view of a continuous spring product of inner coils positioned to intermesh with a continuous

spring product of outer coils to form coaxial coil units; Fig. 5 is a plan view of an innerspring structure of the

invention with a row of coaxial coil units;

Fig. 6 is a diagrammatic plan view in which each coil

pair and coaxial coil unit pair in each row is designated by block lines constituting continuations of the Z-shaped coil interconnection

segments;

Fig. 7 is an enlarged fragmentary top plan view of a portion of the assembly shown in Fig. 6;

Fig. 8 is a top plan view, partially broken away of an alternative embodiment of an innerspring structure of the invention; Fig. 9 is a diagrammatic plan view of the embodiment

of Fig. 8 in which each coil pair and coaxial coil unit pair in each

row is designated by block lines constituting continuations of the Z- shaped coil interconnection segments.

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments

of the invention and, together with a general description of the invention given above, and the detailed description of the

embodiments given below, serve to explain the principles of the invention. Detailed Description of Specific Embodiments Fig. 1 illustrates the innerspring structure 10, which utilizes the reinforced coil units of the present invention. Innerspring structure 10 includes a plurality of coils 12, which are referred to as outer coils for the purpose of this invention. Some of the outer coils 12 are utilized in conjunction with other coils 14, referred to as inner coils, which are placed within certain of the outer coils 12 to form reinforced coil units 16 as described further hereinbelow. Although, the inner coils 14 and respective outer coils 12 are preferably coaxial, each coil and its turns may vary in orientation with respect to the other. Therefore, the terms "inner" and "outer" are used primarily for reference and do not necessarily

indicate the overall coil orientations within the reinforced coil unit 16.

To form the body of innerspring structure 10, the outer coils 12 are arranged side-by-side with each other and are

placed in aligned rows 18. The outer coils 12 consist of a series of

wire turns and each coil has opposing end turns 20, 22 (see Fig.

2). The respective end turns 20, 22 of the coils 12 collectively lie in generally the same opposing planes and define a top face surface 24 and an opposing bottom face surface 26, of the innerspring structure 10. A reinforced border wire 28, which preferably has a diameter greater than the diameter of the wires used to wind the coils 12, 14, is placed around the periphery of the innerspring

structure 10 at the top face surface 24 and the bottom face surface 26. The border wire 28 provides enhanced strength at the

innerspring edges.

In accordance with the principles of the present invention, certain areas of the innerspring structure 10, and specifically, certain coil rows of the innerspring structure, such as row 18b, are made more firm than other coil rows, such as rows 18c and 18d, by utilizing reinforced coil units 16 formed by placing an inner coil 14 within each outer coil 12 of the row. For example,

the inner coil 14 and outer coil 1 2 might be positioned side-by-side

and pushed together at their sides to form an intermeshed coil unit.

Preferably, when so positioned, each inner coil 14 is wound, i.e.,

proceeds in a curved or winding path or direction generally similarly

to its respective outer coil 14 such that the coils are generally

coaxial. For example, inner coil 1 4a is wound in the same direction

as outer coil 1 2a, (the right hand direction from the top face

surface 24 to bottom face surface 26 in Figures 1 and 2). Further,

inner coil 14a preferably has generally the same pitch (turns per unit length) as outer coil 1 2a. However, it should be understood

that the inner and outer coils 14, 1 2 might also wind differently

with different winding directions and/or pitches, although that may

make them more difficult to position together into a coaxial coil

unit.

Each inner coil 14 is placed within an outer coil 1 2,

and as illustrated in Figure 2, the coil within a coil structure forms a

generally coaxial, reinforced coil unit 1 6, which has a double wire

thickness. The outer and inner coils 1 2, 14 are effectively nested

together and extend generally coaxially one with the other such

that coil turns of each coil remain generally adjacent each other in

the mattress and are flexed simultaneously when a load is applied

to face surfaces 24, 26 (see Fig. 2). As discussed above, the corresponding orientations of adjacent turns of the coils change with respect to each other such that one coil turn is inside of or outside of the other turn regardless of whether the coil is

designated as an "inner" or "outer" coil.

The coils 12, 14 of innerspring structure 10 are held

or laced together by a matrix of helical wires. More specifically, referring to Figure 1 , a plurality of spaced-apart helical wires 30 extend longitudinally in the innerspring structure 10 generally perpendicular to the aligned coil rows 18. The helical lacing wires

30 connect the adjacent coils within a row. For example, and as illustrated in Figure 1 , one helical lacing wire 30a would connect

the first and second coils 12a, 12b within the rows, such as rows 18a, 18b and 18c while another helical lacing wire 30b would

connect all of the second and third coils, 12b, 12c, respectively, in the rows 18a, 18b, 18c, etc. The helical wires 30 wrap the respective end turns of the adjacent coils 12, 14 proximate the face surfaces 24,26.

In addition to connecting the coils of a row together, the helical lacing wires 30 also connect the end turns of each inner

coil 14 with the end turns of the respective outer coil 12, as

illustrated in Figure 1 . Therefore, the helical lacing wires 30 form

the reinforced coil units 1 6. As may be seen in row 18b, the top

face surface end turns 20 of outer and inner coils 1 2a, 14a are

connected together by lacing wire 30a. Further, the top end turns

20 of coils 1 2a and 14a are connected with the top face surface end turns 20 of outer and inner coils 1 2b and 14b by lacing wire

30a. Each helical wire 30 also extends generally from end to end

in the innerspring structure 10 and spans between each aligned

row 1 8 of coils and connects the rows of coils to the adjacent rows as illustrated in Figure 1 . In that way, innerspring structure

10 comprises a plurality of coils 1 2, 14, including reinforced

coaxial coil units 1 6, which are connected together in rows by

helical lacing wires 30. The lacing wires then connect together aligned rows 1 8 to form a unitary spring network for the

innerspring structure 1 0.

A helical wire 32 also extends around the periphery of

the innerspring structure 10 with border wire 28. Helical wire 32 is

wrapped to connect the border wire 28 with the top end turns 20

of each peripheral coil which is adjacent the border wire. In that

way, the border wire 28 is secured into the unitary innerspring

structure 10 to provide edge support for the structure. Helical wire

32 also connects the reinforced peripheral coil units 16 to border wire 28 at the ends of row 18b. As illustrated in Figure 3, the border wire 28 is securely wrapped with the end turns of outer and

inner coils 12a, 14a by the windings of the helical wire 32. In accordance with the principals of the present invention, row 18b comprises a plurality of reinforced coil units 16 such that a

mattress utilizing the innerspring structure 10 will have increased firmness or stiffness proximate row 18b. Similarly, other rows of coils or individual coils might be formed as reinforced coil units 16,

including outer and inner coils 12, 14 to selectively vary the

firmness of a mattress in different areas. Still further, the coaxial coil units might be positioned around the periphery of the innerspring structure to strengthen or firm up the edge of the

structure. While only the top face surface 24 of the structure 10 is

illustrated in Figure 1 , the bottom face surface 26 is similarly constructed and connected together utilizing a matrix of helical wires 30 between adjacent coils and the aligned rows and utilizing a second helical wire 32, which extends around a border wire 28.

The helical wire 32, along the bottom face surface 26, is shown schematically by dashed lines in Figure 2.

As illustrated in Figure 1 , the coil end turns 20

proximate upper face surface 24 terminate by wrap sections 34,

which wrap around a portion of a coil turn to form a generally

continuous coil. Similar wrap sections are used proximate the

bottom face surface 26. The reinforced coil units 1 6 of the

invention which are constructed and connected by a matrix of

helical lacing wires 30 provide an innerspring structure 10 with

areas of reinforced firmness. The reinforced coil units 1 6 are

preferably formed utilizing coils 1 2, 14 with wires having similar

diameters to the wires for the remaining outer coils 12 within the

innerspring structure 10. Therefore, thicker wire is not utilized to

increase the firmness in areas of structure 10 resulting in material

cost savings. Furthermore, the innerspring structure 10 with firm areas having reinforced coil units 1 6 may be constructed generally

similarly to a structure which does not utilize reinforced units, thus

maintaining an efficient construction process. While only one row

1 8 is illustrated in the figures as including reinforced coil units 1 6, other coil rows might utilize similar reinforced coil units.

Fig. 5 illustrates an alternative embodiment of an

innerspring structure constructed in accordance with the principles

of the present invention. Innerspring structure 40 includes a

plurality of rows of coils, e.g., 42, 43 and 44 which extend

generally parallel to each other and are adjacent to each other to

form the innerspring structure 40. Each row 42, 43 and 44 of coils

includes coils formed from a continuous length of wire which is

generally wound to form a plurality of spaced coil pairs 45 or

coaxial coil unit pairs 54. The individual coils 45a, 45b of pairs 45

are connected together by Z-shaped interconnection segments 47

and 48 which are disposed sequentially and respectively first in the

upper or top plane 53 of the innerspring structure 40 and then

within the lower or bottom plane 52 of the innerspring structure

(see Figs. 4A and 5). Similarly, the individual coils 54a, 54b of

coaxial coil unit pairs 54 are connected together by Z-shaped

interconnection segments 56, 57 which are disposed sequentially

and respectively first in the top plan 53 and then in the bottom

plane 52 (see Figs. 4A and 5).

As best illustrated in Figs. 4A and 4B, each coil pair 45 or coil unit pair 54 comprises a first right handed coil 45a or coil

unit 54a offset from a second right handed coil 45b or coil unit

54b, preferably having the same number of turns, or the same

pitch, as coil 45a or coil unit 54a. The axes 58 of the coils 45a of

each row, such as row 42, lie within a plane 50 which is parallel

to, but spaced apart from, a second plane 51 within which lie the axes 49 of the offset coils 45b. In a preferred embodiment, the axes 58, 49 of adjacent coils 45a and adjacent coils 45b are equidistant, with the axes being generally perpendicular to the top

and bottom planes 52 and 53 of innerspring structure 40. The coaxial coil unit 54a, 54b of row 43 are similarly spaced and arranged in parallel planes wherein the axes 59, 60 are

perpendicular to top and bottom planes 52, 53.

The coaxial coil units 54a, 54b of row 43 are formed in accordance with the principles of the invention by positioning together a row of inner coils, such as coils 45a, 45b and a row of

outer coils designated 55a, 55b (see Figs. 4B and 5). As discussed above, the reference to "inner" and "outer" coils is for reference purposes only. Preferably, the inner coils 45a, 45b will generally be identical to the outer coils 55a, 55b so that the two rows of inner and outer coils may be easily positioned together to form a row of coaxial coil units 54a, 54b as discussed further hereinbelow (see Fig. 4A).

Referring to Fig. 5, the innerspring structure 40 of the invention will include rows of coils 42, 43, 44, wherein at least one

of the rows, e.g., 43, includes a reinforced coaxial coil unit 54a,

54b for making one or more sections of the structure 40 more firm

than other sections of the structure. Generally, an entire row

would be either single coils 45 or coaxial coil units 54, but half

rows of coaxial units or even a single coaxial unit may be used, if

desired. While Fig. 5 shows a single view for illustrative purposes,

it should be understood that a plurality of adjacent rows like row

43 might be utilized. Furthermore, all of the rows, whether single

coils or coaxial coil units, are preferably positioned and secured in a

similar fashion.

Fig. 4A illustrates a row of coaxial coil units

constructed in accordance with the principles of the present

invention. Specifically, row 43 comprises a plurality of adjacent

coaxial coil unit pairs 54 or coil units 54a, 54b, which are made up

of inner coil pairs 45, arranged as inner coils 45a and 45b, as well

as outer coil pairs 55, including individual outer coils 55a and 55b.

That is, each coaxial coil unit, e.g., 54a, will comprise of inner coil

45a, and an outer coil 55a. As mentioned, in a preferred

embodiment, the inner and outer coils 45a, 55a will generally have

the same shape and will generally be interchangeable.

Referring to Fig. 4B, row 43 of reinforced coaxial coil

units 54 is formed by positioning or intermeshing a row of outer

coils 55a, 55b, with a row of inner coils 45a, 45b. For example, a first row 43a of inner coils 45a, 45b might be positioned as a row

of the innerspring structure 40. Next, a row 43b of outer coils 55a, 55b is positioned adjacent to the row 43a of inner coils 45a,

45b to extend generally parallel thereto such that the inner coil pairs 45 are aligned with the outer coil pairs 55. Each row 43a,

43b is made of a continuous pieces of wire so that the adjacent coils are connected preferably by Z-shaped interconnection

segments. As mentioned, the row of outer coils 55a, 55b may be formed in the same way in which the row of inner coils 45a, 45b is formed, as the designation of inner and outer coils is made for the purpose of reference to describe the unique construction of the

coaxial coil units discussed hereinabove. Preferably, the rows of inner coils 45a, 45b and outer coils 55a, 55b are positioned such that all the coils have the same winding direction as well as the same orientation of the various Z-shaped interconnection wire

segments 47, 48. For consistency, the interconnection segments

of the row of outer coils 55a, 55b are also referenced as 47, 48. In that way, as illustrated in Figs. 4A and 4B, when the adjacent rows 43a, 43b of coils are pushed together to form a row 43 of

coaxial coil units 54 in accordance with the principles of the

present invention, the individual rows 43a, 43b intermesh easily together so that at least one inner coil, e.g., 45a, of each

reinforced coaxial coil unit 54a is wound or positioned coaxially with respect to an outer coil 55a of the coaxial coil unit. When a row 43 of coaxial coil units 54 is formed, the overlapping

interconnection segments 47, 48 are collectively designated as

segments 56, 57, respectively (see Figs. 4A and 5).

As will be appreciated from the following description, the coil interconnection technique utilized to form the coils of the innerspring unit 40 prevents adjacent coils from binding when

compressed even if they are not of hourglass configuration. Thus, a variety of shapes may be employed such as hourglass or potbellied, but the cylindrical shape illustrated is a preferred embodiment.

Rows of reinforced coaxial coil units 54 might be utilized at the sides of the innerspring structure 40 to extend longitudinally therein for strengthening the mattress sides, which receive a lot of pressure from persons sitting thereon. However, in

a preferred embodiment, the rows 43 of coaxial coil units 54 are positioned to lie transverse in the innerspring structure 40 for

forming firmer sections at positions along the length of the

innerspring structure 40 and along the length of a mattress formed

from such an innerspring structure.

Preferably, each innerspring row, 42, 43 and 44 would

generally contain coils therein which are identical to every other

coil in the row and of the same twist direction and pitch (turns per

unit length). That is, each row is generally configured identical,

except rows of coaxial coil units 54 will comprise two rows of

inner and outer coils 45, 55 intermeshed together.

In the preferred embodiment of the invention, the

spacing between the axes 59, 60 of adjacent coils within a row 43

is the same as the spacing between axes 49, 58 of adjacent coils

in the other rows 42 and 44. The same positioning and spacing

would also hold true for two adjacent rows of single inner coil units

45a, 45b or two adjacent rows of coaxial coil units 54. Should a

coil pair 45a, 45b in row 42 be interconnected in the top plane 53

of the innerspring structure 40, the adjacent pair of coaxial coil

units 54a and 54b are also interconnected in the same top plane

53. This is best illustrated in Fig. 5 wherein in row 42, typical

adjacent coils 45a, 45b are interconnected by Z-shaped wire

segments 47 lying within the top innerspring plane 53, and the

adjacent pair of coaxial coil units 54a, 54b are interconnected by a

double Z-shaped wire segment 56 also lying in the same top plane

53 of the innerspring structure 40. This pattern is generally

repeated throughout the entire innerspring structure 40. Similarly, the Z-shaped segments 48 in the bottom plane 52 of the

innerspring structure 40 lie in the same plane with the double

Z-shaped segments 57. This pattern is also repeated throughout

the innerspring structure 40. The result is that Z-shaped segments in the top plane 53 are aligned in columnar fashion and similarly the

Z-shaped segments in the bottom plane 52 are also aligned in columnar fashion. In other words, the Z-shaped segments 47, 56

and 48,57 are aligned both in rows and in columns in the top and bottom planes 52, 53 of the innerspring structure 40.

In order to connect the adjacent rows of coils and coil units, the rows 42, 43, 44 are first positioned so that the Z-shaped

segments which interconnect adjacent pairs of coils within each row, such as segments 47, 48 for a pair of inner coils or single coils 45a, 45b, or segments 56, 57 for a pair of coaxial coil units 54a, 54b, overlap the Z-shaped segments of the adjacent row of coils or coil units. These overlapped portions or sections of the Z- shaped segments are then connected or tied together by helical

wire connectors. Referring to Figs. 4A and 5, a first set of helical

wire connectors, herein designated 61 , is disposed within the top plane 53 of the innerspring structure 40 so as to join together

overlapped portions 62 of upper Z-shaped interconnection segments, such as interconnection segments 47 and 56 as

illustrated in Fig. 7. Similarly, a second set of helical wire connectors, herein designated 63, lie within the bottom plane 52 of the innerspring structure 40 and serve to join together overlapped portions 64 of lower Z-shaped interconnection segments, such as

48 and 57. In Fig. 5, the left side illustrates the lower plane 52 of the innerspring structure to show the connector 63 and Z-shaped segments 48. As evident in Fig. 4A, the length of each helical wire connector is preferably approximately the same as the length of the rows, and the helical wire connectors 61 , 63 extend generally parallel to the rows. As illustrated in Fig. 4A, the helical wire connectors 61 , 63 also connect together the row of adjacent inner coils 45a, 45b, and the row of adjacent outer coils 55a, 55b. In that way, the inner coils 45a, 45b are maintained generally coaxial and intermeshed with the outer coils 55a, 55b to collectively form

the coaxial coil units 54a, 54b of the invention. The assembly of the helical wire connectors to the rows of continuous coils may be accomplished on an assembly

machine. In such a machine, the adjacent rows of coils are positioned so that the sections 62, 64 of the adjacent Z-shaped

segments 47, 56 and 48, 57, respectively, are in overlapping relationship. A helical wire is then rotated or screwed onto the

overlapping sections 62, 64 of the Z-shaped segments. In forming a row of reinforced coaxial coil units 54 in accordance with the

principles of the present invention, a row of inner coils 45a, 45b must be nested or positioned with a row of outer coils 55a, 55b

before any helical wire connectors 61 , 63 are positioned over the overlapping sections 62, 64. After completion of the threading of a

particular helical wire connector onto the overlapped sections 62, 64 of the Z-shaped segments, the now connected adjacent rows of

coils and/or coaxial coil units are indexed forwardly and another pair of upper and lower helical wire connectors 61 , 63, are

threaded over the next row of coils 45a, 45b, or the next row of coaxial coil units 54a, 54b, depending upon the construction of the

next row. The process is repeated for the desired length of the mattress, row upon row, after which the spring assembly is removed from the machine. Referring now to Fig. 7, it will be seen that the

diameters of the wire making up the helical wire connectors 61 , 63

are preferably approximately one-fourth (1 /4) the radius of the overlapped sections 62, 64 of the Z-shaped segments. This

relationship of having the radius of the Z-shaped segments, over

which the helical wire connector 61 , 63 is threaded, approximately

eight times the radius of the helical wire, has the effect of permitting several rotations 65 of the helical wire connector to pass through and lock adjacent overlapped sections together. So locked or interconnected, the adjacent coils or coaxial coil units are free to pivot relative to each other but are locked against relative longitudinal or lateral movement. In other words, this relatively small diameter helical coil, when used to lock the overlapped large radius sections 62, 64 of the segments together, permits only relative pivotal movement between the adjacent interconnected coils.

Referring now to Fig. 6, each block 70 represents the effective outline of a typical top plane Z-shaped interconnection segment 47 in coil row 42. Similarly, each block 72 represents the outline of a typical top plane Z-shaped interconnection segment 56 in row 43 containing the coaxial coil units 54a, 54b of the invention. Each block 71 represents the outline of a typical bottom plane Z-shaped interconnection segment 48 in coil row 42 and

each block 73 represents the outline of a typical bottom plane

Z-shaped interconnection segment 57 in coil row 43. Thus, as

apparent from the diagram in Fig. 6, the blocks 70, 72 and 71 , 73

representing load supporting units. Each of these units 70, 72 and

71 , 73 are overlapped such that the effect of the construction of

the innerspring structure 40 is a very densely packed innerspring

assembly with a relatively high count of coils. Furthermore, coil

row 43 provides load bearing units which are firmer, stronger and

more supportive according to the description of the invention.

Referring now to Figs. 5 and 7, it will be noted that

the several rotations 65 of the helical wire connectors 61 , 63

which pass around and lock adjacent overlapped coil segments 62,

64 are all centered in a common transverse plane 75. It will be

further noted that this plane 75 passes through the vertical axes

58, 59 or 49, 60 of all of the coils or coaxial coil units contained in

a transverse column. Consequently, each coil or coil unit of a row

is connected to two coils or coaxial coil units of the adjacent rows

by several rotations 65 of the helical connectors 61 , 63 the center

planes 75 which are located in a diametrical plane defined by the

vertical axes 58, 59 or 49, 60 of the coils or coil units. This

location of the axes of the coils or coil units relative to the location

and shape of the overlapped and connected segments 62, 64 has

been found to prevent lateral deflection or distortion of the coils

when the coils are fully compressed.

Once the various rows and coils are assembled into

the innerspring structure 40 of the invention, a border wire, like

that shown in Figs. 1 -3, might be utilized to finish the structure.

To that end, the border wire is secured to the outer peripheral coils

of the adjacent rows, such as by a helical coil 32. Other

connecting mechanisms for fixing the border wire to the innerspring

structure 40 might also be utilized.

Figs. 8 and 9 illustrate another embodiment of the

invention in the application made with a continuous coil spring

product similar to those illustrated in Figs. 4A-7. The construction is illustrated diagrammatically on the top plan view of Fig. 8. In

general, the spring assembly of Figs. 8 and 9 is identical to the

spring assembly of Figs. 4A-7, except that the coils are positioned

with the interconnecting Z-shaped segments such that the vertical

axes of all of the coils of a single row are located in the same

vertical plane 80, rather than alternatively staggered in two

different planes as shown in Figs. 4A-7.

The Z-shaped segments, rather than extending

outwardly from one side only of each coil extend outwardly beyond

both sides of each coil so that this construction has the same

advantages of the embodiments of the Figs. 4A-7, and it minimizes

or eliminates any tendency of the coils to overlap or contact

adjacent convolutions of the same coil. Specifically, in this

embodiment each row of coils 82, 84, 86 is formed from a

continuous length of wire and each wire forms a plurality of spaced

coil pairs 88 interconnected by substantially Z-shaped wire

segments 89 disposed in the top plane of the innerspring structure

90. In the bottom planes, substantially Z-shaped wire segments 91

interconnect adjacent coil pairs 88 of the innerspring structure 90.

In accordance with the principles of the present

invention, each innerspring 90 will preferably contain at least one

row 84 of coaxial coil pairs 92. Each pair 92 of coils 92a, 92b will

comprise a pair of inner coils 88a, 88b, and a pair of outer coils

94a, 94b which are preferably positioned and intermeshed together

by the method described hereinabove with respect to Figs. 4A-7.

That is, rows of inner coils 88a, 88b are pushed together with

rows of outer coils 94a, 94b to form coaxial coil units in

accordance with the present invention which are collectively

referred to as coil units 92a, 92b. That is, for example, coil unit

92a will include an inner coil 88a, and an outer coil 94a and each

coil unit 92b will include an inner coil 88b and an outer coil 94b.

The coil units 92a, 92b are connected by Z-shaped interconnected

segments 93, 95 in the top and bottom planes, respectively.

Each coil pair 88, 92 comprises a first right handed

coil 88a or coil unit 92a offset from a second right hand coil 88b or

coil unit 92b preferably having the same number of turns as coil

88a or coil unit 92a, respectively. However, the axes of coils 88a,

88b and coil units 92a, 92b lie within the same plane 80 containing

the axes of the adjacent coils and coil units. While preferably, the

coils of each row generally have the same diameter twist direction

and pitch, alternative twist directions diameters or pitches may still

be utilized in practicing the present invention.

In the embodiment of Figs. 8 and 9, the corners of the

interconnecting Z-shaped segments are both located outwardly

from the circumference of the coils 88 and coils units 92 in both

the top and bottom planes of the innerspring structure 90. The

outward spacing of the Z-shaped segments facilitates

interconnection of the overlapped portions of the Z-shaped

segments by helical spring connectors 98, as discussed above.

Referring to Fig. 8, it will be noted that several

rotations 100 of the helical lacing wire connector 98 pass around

and lock adjacent overlapped segments 102 of the coils to coils or

coil units of the adjacent rows. It will further be noted that the Z-

shaped segments are all shaped and positioned so that the locked,

overlapped segments 102 are all in a common transverse plane 104

which passes through the axes 106 of all the coils and coaxial coil

units contained in a transverse column. Consequently, each coil or

coaxial coil unit is connected to two other coils or coil units of

adjacent rows by connectors 100 having centers 104 which are

located is a diametrical plane of the coils and coil units as defined

by the axes 106.

Referring now to Fig. 9, each block 1 10 represents the

effective outline of a typical top plane Z-shaped interconnection

segment 89. Similarly, each block 1 1 2 represents the outline of a

typical top plane Z-shaped interconnection segment 93 in the row

containing the coaxial coil units 92a, 92b of the invention. Each

block 1 1 1 represents the outline of a typical bottom plane Z-shaped

interconnection segment 91 and each block 1 1 3 represents the

outline of a typical bottom plane Z-shaped interconnection

segment 95. Thus, as apparent from the diagram in Fig. 9, the

blocks 1 10, 1 1 2 and 1 1 1 , 1 13 representing load supporting units.

Each of these units 1 10, 1 1 2 and 1 1 1 , 1 1 3 are overlapped such

that the effect of the construction of the innerspring structure of

Figure 9 is a very densely packed innerspring assembly with a

relatively high count of coils. Furthermore, the coil rows of Figure

9 provide load bearing units which are firmer, stronger and more

supportive according to the description of the invention.

Several different coil configurations have been

illustrated for practicing the present invention; however, in addition

to the individual coils and continuous coil products illustrated, other

coil products might also be utilized. In accordance with the

principles of the invention, Bonnell coils might be utilized, as well

as knotted coils, e.g., offset coils, and unknotted coils.

While the present invention has been illustrated by a

description of various embodiments and while these embodiments

have been described in considerable detail, it is not the intention of

the applicants to restrict or in any way limit the scope of the

appended claims to such detail. Additional advantages and

modifications will readily appear to those skilled in the art. The

invention in its broader aspects is therefore not limited to the

specific details, representative apparatus and method, and

illustrative example shown and described. Accordingly, departures may be made from such details without departing from the spirit or

scope of applicant's general inventive concept.

What is claimed is: