JP2011510793A - Variable coil density anisotropic inner spring - Google Patents

Abstract

  A variable coil density anisotropic inner spring in which the arrangement and density of a coil or spring unit varies between one or more regions or areas, wherein the inner spring has a different average spring rate in different zones or regions. Various anisotropic arrangements of coils in the inner spring are disclosed.

Description

  The present invention relates generally to the field of support structures and systems, and more particularly to flexible support structures including springs.

  Spring systems for mattresses and other rebound support structures used in furniture and seats typically have an array of interconnected springs or other springs that support the rebound support surface. The mattress internal spring (“inner spring”) typically has a matrix of multiple individual spring units interconnected to have parallel rows and columns. One of the most common types of inner springs for mattresses can be formed by an automated wire forming process. In this inner spring, multiple rows of helical wire springs or “coils” are manufactured and arranged to be inserted into the inner spring assembler. The inner spring assembler connects adjacent rows of coils by a lacing wire extending between the rows that traverses the length of the inner spring. The spacing between the coils in each row is uniform, can be set by adjusting the inner spring assembler, and can be held in an appropriate position by the racing wire. Inner springs of different sizes are formed by changing the number of coils in each row and the total number of rows. However, the coil density and resulting spring rate, support properties and feel (eg, stiffness, bounce, etc.) are uniform throughout the inner spring where the coils are evenly distributed. Some inner springs further have a large-diameter border wire, and the border wire is connected to the upper part of the coil around the inner spring.

  The sleeping mattress is formed using various materials above or around the inner spring. Some materials are provided to enhance the structure and rebound characteristics of the inner spring (eg, support characteristics at the edges of the inner spring and mattress). For example, US Pat. No. 5,787,532 discloses a foam wall structure that conforms to the peripheral coil of the inner spring of the mattress and stiffens the edge of the mattress. The uniform and isotropic spring characteristics and support characteristics of the inner spring obtained as a result of the coil or spring unit being equidistantly provided are various kinds of materials provided around the inner spring and connected to the inner spring. Regardless of the amount of change.

  The present disclosure relates to anisotropic inner springs in which the arrangement and density of coils or spring units differ between one or more regions or areas. In this specification, the term “anisotropic” is used in a physical sense with respect to the inner spring. That is, having different physical properties in different areas, zones or regions or different dimensions / shapes. When used with an inner spring, anisotropy is the density of the spring or coil in various regions of the inner spring and the resulting average spring rate and / or stiffness is the coil density in one or more regions of the inner spring. Mean that the coil density and arrangement in different regions of the same inner spring and a coil density and arrangement different from the average spring rate are obtained. The area of the anisotropic inner spring of the present disclosure is defined by a group of coils arranged in relative positions with a common spacing or density. The coil spacing within a region varies from region to region, and therefore the coil density varies from region to region. The pad material and upholstery material that form the mattress in combination with the inner spring may be selected and arranged according to the coil density of the region of the inner spring that is the lower layer of these materials.

  Another aspect of the present disclosure and invention resides in an anisotropic inner spring having a different number of coils in different regions. The inner spring includes a plurality of interconnected coils arranged in parallel with their axes parallel to each other and with their ends in a common plane. The inner spring has a plurality of regions defined by a group of coils having axes that are spaced apart by a common distance. The plurality of regions are provided with a first region where the coil axis is spaced apart by a first distance and a second region where the coil shaft is longer than the first distance. A second region. The coils in the plurality of regions of the inner spring are interconnected by a lacing wire that extends between the coils from one region of the inner spring to another region of the inner spring.

  A further general concept of the present disclosure and invention is that a plurality of interconnected, arranged in parallel, with their ends parallel to each other in a common plane defining opposing support surfaces of the inner spring. An inner spring of the type that can be used in a mattress or other flexible support system with an additional coil. The coil axes of the first coil group are provided at a first common distance apart, the first coil group defines the first region of the inner spring, and the coil axis of the second coil group is the first coil axis. The second coil group defines a second region of the inner spring, with a second common distance longer than a fixed distance of 2. Thereby, the density of the coil in the first region is higher than the density of the coil in the second region, and the coil density in the first region is higher than the coil density in the second region.

  These and other concepts and aspects of the present disclosure and invention will now be described in more detail with reference to the accompanying drawings.

FIG. 1 is a plan view showing an embodiment of a variable coil density anisotropic inner spring and an enlarged view of an edge region thereof. FIG. 2 is a side view of the variable coil density anisotropic inner spring of FIG. FIG. 3 is a plan view illustrating another embodiment of the variable coil density anisotropic inner spring of the present disclosure, having a unique coil pattern, arrangement and zones. FIG. 4 is a plan view illustrating another embodiment of the variable coil density anisotropic inner spring of the present disclosure, having a unique coil pattern, arrangement and zones. FIG. 5 is a plan view illustrating another embodiment of the variable coil density anisotropic inner spring of the present disclosure, having a unique coil pattern, arrangement and zones. FIG. 6 is a plan view illustrating another embodiment of the variable coil density anisotropic inner spring of the present disclosure, having a unique coil pattern, arrangement and zones. FIG. 7 is a plan view illustrating another embodiment of the variable coil density anisotropic inner spring of the present disclosure, having a unique coil pattern, arrangement and zones. FIG. 8 is a plan view illustrating another embodiment of the variable coil density anisotropic inner spring of the present disclosure, having a unique coil pattern, arrangement and zones. FIG. 9 is a plan view illustrating another embodiment of the variable coil density anisotropic inner spring of the present disclosure, having a unique coil pattern, arrangement and zones. FIG. 10 is a plan view illustrating another embodiment of the variable coil density anisotropic inner spring of the present disclosure, having a unique coil pattern, arrangement and zones. FIG. 11 is a plan view illustrating another embodiment of the variable coil density anisotropic inner spring of the present disclosure, having a unique coil pattern, arrangement and zones. FIG. 12 is a plan view illustrating another embodiment of the variable coil density anisotropic inner spring of the present disclosure, having a unique coil pattern, arrangement and zones.

  As shown in the drawings, the variable coil density anisotropic inner spring, denoted by reference numeral 10 throughout this specification, is assembled from a plurality of springs or coils 20. The spring or coil 20 is shown as a generally helical coil having first and second ends (or upper and lower ends) 21, 22 and a coil body 23. The coil body 23 has a spiral shape as shown, and extends between coil ends. Other types and shapes of springs or coils can also be used in accordance with the principles of the present disclosure. The present disclosure primarily relates to the placement and relative position of the spring or coil within the inner spring, and thus is not limited to a particular type or shape of spring or coil. As used herein, the term “coil” means and includes any form of spring and coil that can be used within an inner spring constructed in accordance with the principles of the present disclosure.

  As shown in FIG. 1, the inner spring 10 is composed of a plurality of coils 20 arranged in a matrix or array. The coils are generally arranged in rows R and columns C, the coil axes are parallel, and the ends of the coils are each in a common plane. These planes define the surface support or spring surface of the inner spring. The number of coils in each row and column depends on the overall design size of the inner spring. The width W of the inner spring is generally determined by the number of coils in each row R and the spacing. The length L of the inner spring is generally determined by the number of coils in each row C and the spacing. Although the width is W and the length is L, such reference numerals are merely used for explanation, and the relative anisotropic arrangement of the coils is not limited to the illustrated form.

  FIG. 1 shows a variable coil density anisotropic inner spring as an example. In this variable coil density anisotropic inner spring, the rows Cl1 to Cl3 and Cr1 to Cr3 are respectively located at the peripheral edge or peripheral region extending in the longitudinal direction of the inner spring 10, and between these rows (or between the coil axes) Are arranged so as to be narrower than the horizontal interval between the coils in the remaining row C. In the figure, the adjacent three rows Cl1 to Cl3 and Cr1 to Cr3 that define the peripheral edge or peripheral region extending in the longitudinal direction of the inner spring are each grouped, but the present disclosure is another number or other provided at intervals. Contains a grouping column or row. The number or grouping of such columns or rows is a coil column in the inner spring that forms a coil group or region different from other coil groups or regions due to the difference in relative spacing between the coil axes in the group or region. Or different from other numbers or other groups of rows, ie more or less. For an inner spring of a mattress, the present disclosure further narrows the spacing between coil axes and columns along a longitudinally extending peripheral region defined by columns Cl1-Cl3 and rows Cr1-Cr3 in this embodiment. Provides coil anisotropy with higher coil density. This increases the stiffness and stiffness along the longitudinally extending edge region of the mattress. This is desirable to increase resistance to edge support, anti-roll-off, and permanent setting by using a longitudinally extending edge as the seating surface.

  In conventional inner springs, the relative lateral spacing between the helical coils in each coil row, i.e. the lateral distance between two adjacent coil axes or the lateral distance between the maximum radius of two adjacent coils is usually Measured and set with reference to coil pitch. The coil pitch is a linear distance from one winding portion of the coil to the adjacent winding portion, and is measured at the maximum radius portion of the coil winding portion and is parallel to the longitudinal axis of the coil. A typical uniform coil interval of the inner spring is, for example, 2 pitches. This means that the lateral distance between each coil and the adjacent coil in the same row is a distance of 1 to 2 times the coil pitch. The coil spacing set in this way determines the coil density of the inner spring and the overall spring rate. The coil spacing between adjacent coil rows is generally very narrow and may touch at one point or overlap to some extent. This is necessary for the small diameter spiral lacing wire to be wound around the adjacent windings at the coil ends. As described above, according to the present disclosure, the horizontal interval between the coils in each row can be adjusted and changed by, for example, setting the inner spring assembler interval. As shown in FIG. 1, a typical example of the horizontal spacing of the coils in a row is zero or one touching spacing in columns Cl1-Cl3 and Cr1-Cr3, and 1-2 pitches in the remaining coils in each row. That's it. The present disclosure includes any spacing or variable spacing between coils or groups of coils in a row, which may or may not be repeated from row to row.

  Other examples and embodiments that do not limit the invention include reducing the coil spacing at one side or one end of the inner spring; along the width or length of the inner spring, or along the width and length. Increasing or decreasing the interval gradually or abruptly; by alternately changing the interval, for example, the coil interval in the coil pair or coil group becomes narrower or one point touching interval, and more than other coil pairs or coil groups Make wide spacing; and change the coil spacing from row to row, for example, to make the coil spacing narrower or touch at one point in one row and to make the coil spacing wider in another row Including that. About the automatic assembly of the inner spring of this indication, the variable coil density anisotropic inner spring of this indication can be manufactured using the arbitrary coil space | intervals which an inner spring assembler can set.

  The variable coil density anisotropic inner spring of the present disclosure can be manufactured with the same total number of coils as a conventional isotropic inner spring of equal overall size, eg, twin size, queen size or king size. This is because the coil spacing saved in the higher density area is used in the lower density area.

  According to another aspect of the inner spring design of the present disclosure, as a result of varying the lateral spacing in the coil row R, each region itself is isotropic when there are regions having different coil densities in the inner spring. A uniform spring effect and support may be provided. The boundary between the low coil density region and the high coil density region contributes to the torsional rigidity of the entire inner spring, whether in the horizontal direction or the vertical direction. For example, the relatively high coil density in the region defined by the rows Cl1-Cl3 and Cr1-Cr3 causes the central region to deflect laterally by applying a lateral or torsional force to the remaining central region coils. Or provided mechanical resistance against the tendency to compress.

  Another aspect of the present disclosure, particularly the aspect of the anisotropic nature of the inner spring of the present disclosure, resides in the wire gauge used to form the coil. The wire gauge may vary depending on the coil position and density (ie spacing). For example, coils located in denser areas or regions, such as coils in rows Cl1-Cl3 and Cr1-Cr3, have a different (smaller or larger) size than the wires of the coils in the remaining areas with lower coil density. It may be formed of a gauge wire. For example, when the coils in the rows Cl1 to Cl3 and Cr1 to Cr3 are formed with heavier gauge wires, the inner spring with a stiffer peripheral region is formed than when all the coils of the inner spring are formed with the same gauge wire. Manufactured. Associated with this design variable is the size and structure of the coil. For example, a coil located in a higher coil density region may have a different diameter (larger or smaller) from a coil end and / or helical coil body than a coil in a lower coil density region. Good). By varying these parameters, the overall spring rate of the various regions of the inner spring can be configured to have similar specifications. Another design example for this aspect of the present disclosure that does not limit the invention is that the coil located at the periphery of the inner spring is formed of a relatively heavy gauge wire to further contribute to edge support and anti-roll-off characteristics. is there.

  FIG. 3 shows another embodiment of the variable coil density anisotropic inner spring 10. In this embodiment, in the variable coil density anisotropic inner spring 10, the coils 20 are arranged in a row C having a repeating pattern of lateral intervals along the width W of the inner spring. The longitudinally extending edge of the inner spring is formed by closely spaced rows Cl1-Cl2 and Cr1-Cr2, providing edge support similar to that described with reference to FIG. A central region extending in the longitudinal direction of the inner spring is defined by coil rows Cln and Crn that are adjacent to each other at a narrow interval or are in contact with each other at one point. The longitudinally extending central region having a relatively high coil density and the resulting spring rate can be enlarged by additional coil rows adjacent at close intervals. In the area between the longitudinally extending peripheral region and the longitudinally extending central region, the coil density and the resulting spring rate is relatively low. The reason is that the horizontal interval of the row Ci of the coil 20 is increased. The wire density of the coils in the row Ci may be the same as or higher than the wire density of the coils in the other rows. Furthermore, the material that is provided above the coil and forms the mattress may be selected and arranged according to the coil density of the region that is the lower layer of the material in the inner spring.

  FIG. 4 shows a right / left version of the anisotropic variable coil density inner spring 10 of the present disclosure. In this version, one lateral half or region of the inner spring 10 has a higher coil 20 density than the other lateral half or region. This type of inner spring is suitable for use on "two-person" mattresses with a hard side and a soft side that are constructed to have unique support characteristics and feel on each side half or part of the sleeping surface ing. As shown in the drawing, the interval between the rows Cl of the coils 20 in the left half of the inner spring or a part thereof may be a standard contact point or a substantially single point contact. The spacing between the 20 rows Cr is relatively wide so that the coil density and average spring rate may be low. For example, the interval between the coil rows Cr may be one pitch or greater than the interval between the coil rows Cl. In this embodiment, the spacing or row R is uniform along the length of the inner spring, but does not have to be at one point touching or substantially at one point touching as shown, rather it is a coil. There may be some spacing between the lines.

  FIG. 5 shows a head / foot or upper / lower body version of the anisotropic variable coil density inner spring 10 of the present disclosure. In this version, one of the upper or lower body regions of the inner spring 10 has a higher coil 20 density than the other. This type of inner spring is suitable for use in mattresses that are configured to have unique support characteristics and feel in the upper or lower body region of the sleeping surface. As shown in the figure, the spacing between the coils 20 in the row Ru in the upper region of the inner spring positioned at the head of the mattress, for example, may be a spacing at one point or a spacing at one point. The coil 20 spacing in row Rl is relatively wide, so that in this region, the coil density and average spring rate may be lower than in the region defined by coil row Ru. For example, the interval between the coil rows Cr may be one pitch or greater than the interval between the coil rows Cl. As a result of the relatively large coil spacing in row Rl, the number of columns Cl is less than the number of columns Cu. This is shown as a 12:16 ratio in the figure, but other ratios are possible depending on the coil spacing of row Rl. Further, in this embodiment, the longitudinal intervals of the rows Ru and Rl are uniform along the length direction of the inner spring, but as shown in the drawing, it is necessary to be an interval that contacts at one point or an interval that contacts at substantially one point. Rather, there may be a certain distance between the coil rows Ru and Rl.

  FIG. 6 illustrates yet another embodiment of the anisotropic variable coil density inner spring of the present disclosure. In this embodiment, the central region extending in the longitudinal direction of the inner spring 10 is defined by the coil array Cc that contacts at one point, and has a higher coil density and spring rate than the regions on both sides defined by the coil array Cl. Offering an area. As with other inner spring structures, the upper layer material used to make up the mattress, in particular the pad material layer under the upholstery, has the support characteristics and spring rate of the lower layer of these materials in the inner spring. It can be selected and arranged accordingly. For example, in this case, denser pad material and / or additional layers in both sides of the region are selected and arranged to compensate for the lower spring rate in both sides or to act at the lower spring rate.

  FIG. 7 illustrates another embodiment of the anisotropic variable coil density inner spring of the present disclosure. In this embodiment, the coil spacing pattern is repeated for each coil row, and the repeating pattern is not in phase with the next adjacent coil row. For example, when starting from the coil row R1 and looking from the right to the left, a pattern of three coils having a narrow interval or an interval that touches at one point and three coils having an interval is repeated throughout the row. In the next adjacent row R2, the same pattern is repeated, but the pattern starts with three coils spaced at the right end. Thereafter, the coil spacing pattern is repeated alternately. Therefore, the coil density varies within each row Rn, and further varies from row to row in the entire inner spring.

  FIG. 8 illustrates another embodiment of the anisotropic variable coil density inner spring 10 of the present disclosure. In this embodiment, the distance between the rows R of the inner springs gradually increases along the length direction of the inner springs. The increase in the distance may be from the head to the foot or vice versa. Although shown as an example, the row R1 and the row R2 may be in contact with each other at one point or substantially at one point, and these may be repeated or increased according to the pitch. May be. For example, the pitch may be increased by 1 pitch or 1/2 pitch per row. The increase in line spacing may be linear or non-linear. The spacing between rows R is wider than the spacing at a single point, resulting in no coils in the entire row. To connect the coils, the laces wire 21 extends in the longitudinal direction and interconnects the coils that are adjacent or touching at one point in each row.

  FIG. 9 illustrates another embodiment of the anisotropic variable coil density inner spring 10 of the present disclosure. In this embodiment, the distance between the row R and the column C does not contact at one point except for the end row Re, and the distance between the coils in the column is preferably 1 pitch or more. The coil spacing in row R is every other column C. The coil spacing in column C is not in phase with the adjacent columns, so the coils in adjacent columns are not laterally aligned except in row Re. Conversely, every other row C coil is aligned laterally. Thereby, a desired offset pattern of the distributed coil arrangement is formed. This offset pattern is isotropic throughout the main area of the inner spring and has a higher density at the edges, rows Re and / or longitudinally extending sides. Further, although the lacing wire 21 extends in the longitudinal direction in the figure, conventional lateral lacing is also possible in which the outer diameters of the laterally adjacent coils generally match.

  FIG. 10 shows an embodiment of the zone-type anisotropic variable coil density inner spring 10 of the present disclosure. In this embodiment, there are multiple (eg, three) zones or regions Ru, Rl, Ru with different densities of the coil 20. The coils 20 are generally arranged in the longitudinal direction, for example, from the head to the foot, to form the anisotropic inner spring 10. One way in which the coil density of the zones or regions Ru, Rl can be different from those of other zones or regions is to change the spacing of the row C. As in other embodiments of the inner spring 10, the coil spacing in the row C need not be the same in one region, for example, the region Ru of the head of the inner spring and the other region Ru of the foot of the inner spring.

  FIG. 11 shows still another embodiment of the zone-type anisotropic variable coil density inner spring 10 of the present disclosure. In this embodiment, there are a plurality of (eg, 5) zones or regions Ru, Rl having different densities of the coil 20. The coils 20 are generally arranged in the longitudinal direction, for example, from the head to the foot, to form the anisotropic inner spring 10. As with the embodiment of FIG. 10, one way in which the coil density of the zones or regions Ru, Rl can be different from that of other zones or regions is to change the spacing of row C. As in the embodiment of FIG. 10, the coil spacing in row C need not be the same in one region, for example, the region Ru of the inner spring head and the other region Ru of the inner spring foot.

  FIG. 12 shows still another embodiment of the zone-type anisotropic variable coil density inner spring 10 of the present disclosure. In this embodiment, there are a plurality of (for example, seven) zones or regions Ru, Rl having different densities of the coil 20. The coils 20 are generally arranged in the longitudinal direction, for example, from the head to the foot, to form the anisotropic inner spring 10. Similar to the embodiment of FIGS. 10 and 11, one way in which the coil density of the zones or regions Ru, Rl can be different from that of other zones or regions is to change the spacing of the row C. Similar to the embodiment of FIGS. 10 and 11, the coil spacing in row C need not be the same in one region, for example, the region Ru of the head of the inner spring and the other region Ru of the foot of the inner spring. The zones or regions in the embodiment of FIGS. 10-12 and other embodiments are aligned with or in alignment with the upper and / or lower material layers that are disposed relative to the inner spring to form the mattress. Also good.

The above are exemplary embodiments of the principles and concepts of the present disclosure, and the present disclosure encompasses and includes other types of anisotropic inner springs having variable coil density.

Claims (30)

  An anisotropic variable coil density inner spring, a plurality of coils interconnected in an anisotropic array, wherein the relative spacing between the axes of the coils arranged in rows and columns in the array A plurality of non-constant coils throughout the inner spring, and a lacing wire extending between the coils and interconnecting the coils in the anisotropic array to maintain a relative spacing between the axes of the coils. Anisotropic variable coil density inner spring provided.   2. The inner spring according to claim 1, wherein coils of at least two coil rows of the array located at a peripheral edge extending in a longitudinal direction of the inner spring are provided at a narrower interval than other coils in the array.   2. The inner spring according to claim 1, wherein a distance between coils in each coil row of the inner spring is not constant, and a distance between coils in each coil row of the inner spring is constant.   The inner spring according to claim 1, wherein a coil density in a peripheral region extending in a longitudinal direction of the inner spring is higher than a coil density in other regions of the inner spring.   The inner spring according to claim 1, wherein an average spring rate of a peripheral region extending in a longitudinal direction is higher than an average spring rate of other regions of the inner spring. An inner spring,
An anisotropic array of interconnected coils arranged in rows and columns, wherein the number of coils in each column and each row is common,
At least two coil rows are spaced apart by a first distance, and at least two other coil rows are spaced apart by a second distance longer than the first distance;
An inner spring in which the coils are interconnected by a racing wire provided in a direction across the coil row between the coil rows.   The inner spring according to claim 6, wherein each of the peripheral regions extending in the longitudinal direction of the inner spring includes at least two coil rows that are spaced apart from each other by the first distance.   A central region extending in the longitudinal direction includes at least two coil rows spaced apart by the first distance, and a coil row provided on a side portion of the central region extending in the longitudinal direction extends in the longitudinal direction. The inner spring according to claim 6, wherein the inner spring is spaced from the extending central region by the second distance.   7. The inner spring according to claim 6, wherein the racing wire extends between coil rows that are spaced apart by the first distance and between coil rows that are spaced apart by the second distance. 8. . An anisotropic inner spring having a different number of coils in different regions,
A plurality of interconnected coils arranged in a state where the axes are parallel and the ends are provided in a common plane, and the inner springs are provided with a shaft provided at a distance of a common distance. A plurality of regions defined by a coil group having the first region in which the coil axis is spaced apart by a first distance, and the coil axis is the first distance. A second region spaced apart by a longer second distance, and
An anisotropic inner spring, wherein the coils in the plurality of regions of the inner spring are interconnected by a lacing wire extending between the coils from one region of the inner spring to another region of the inner spring.   The anisotropic inner spring of claim 10, wherein the plurality of interconnected coils are arranged in columns and rows.   The anisotropic inner spring according to claim 11, wherein the first region includes at least a part of a peripheral edge of the inner spring.   The anisotropic inner spring according to claim 10, wherein the first region includes at least two coil rows or coil columns adjacent to each other.   The anisotropic inner spring according to claim 10, wherein the second region includes at least two coil rows or coil columns adjacent to each other.   The anisotropic inner spring according to claim 10, wherein the first region extends along a length direction of the inner spring.   The anisotropic inner spring according to claim 10, wherein the coil rows of the inner spring are spaced apart by a certain distance in the entire area of the inner spring.   The anisotropic inner spring according to claim 10, wherein the racing wire extends between the coil rows so as to traverse the coil row from one region of the inner spring to another region of the inner spring.   The anisotropic inner spring according to claim 10, wherein the coil rows of the inner spring are provided at a predetermined distance in the entire area of the inner spring.   The anisotropic inner spring according to claim 10, wherein the coil density in one area of the inner spring is at least 25% of the coil density in another area of the inner spring.   The anisotropic inner spring according to claim 10, wherein a region of the inner spring having a higher coil density than another region includes at least a part of a peripheral edge of the inner spring.   The anisotropic inner spring according to claim 10, wherein a region of the inner spring having a higher coil density than another region is at least partially located in a central region of the inner spring. An inner spring,
A plurality of interconnected coils arranged in a state in which the axes are parallel and the ends are respectively provided in a common plane that defines the mutually opposing support surfaces of the inner spring;
Coil axes of the first coil group are provided at a first common distance apart, the first coil group defining a first region of the inner spring;
A coil axis of the second coil group is provided at a second common distance longer than the first common distance, and the second coil group defines a second region of the inner spring. And
Thereby, the density of the coil of the first region is higher than the density of the coil of the second region, and the coil density of the first region is higher than the coil density of the second region.   The inner spring according to claim 22, wherein the first region of the inner spring has a higher spring rate than the second region of the inner spring.   23. The inner spring of claim 22, wherein all of the coils of the inner spring are located in rows that extend in parallel through the first region and the second region.   23. The inner spring of claim 22, wherein all of the coils of the inner spring are located in a row extending in parallel through the first region and the second region.   23. The inner spring according to claim 22, wherein the coils are arranged in columns and rows and are spaced by a common distance within each coil row of the inner spring.   23. The inner spring according to claim 22, wherein the coils are arranged in columns and rows and are spaced by a common distance within each coil column of the inner spring.   23. The inner spring of claim 22, wherein the coils are interconnected by a racing wire that extends between each coil row from the first region to the second region of the inner spring.   A third coil group that defines a third region of the inner spring; and a coil axis in the third coil group includes an interval between the coils in the first region and the second region in the second region. 23. The inner spring according to claim 22, wherein the inner spring is provided with a third common distance different from the coil spacing.   The inner spring according to claim 22, provided in a single-side mattress.

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