The present invention relates to mattresses, and in particular to a zoned foam mattress.
A comfortable mattress is crucial to providing high quality sleep. One way of making a mattress more comfortable is to provide multiple lateral zones of differing firmness that correspond to different areas of the body of the user of the mattress. Different portions of the user's body exert different pressures on the mattress. Thus, the lateral zones under the user's shoulders and hips are made of softer foam than the lateral zones under the user's torso and legs in order to allow the user's shoulders and hips to sink into the mattress and to allow the user's spine to remain straight.
A typical zoned foam mattress is made by gluing together lateral rectangular blocks of foam in which adjacent blocks have differing hardnesses. The indentation load deflection (ILD) is one measure of hardness defined in the ISO 2439 standard. The standard defines ILD as the force that is required to compress the foam to a specified percentage of its original thickness using a circular plate of fifty square inches. For example, the 25%-compression ILD is the most commonly used ILD and is the number of pounds required to achieve the 25% compression. ILD is also measured at 40% and 60% compression.
Zoned foam mattress 10 is a Queen size mattress that is sixty inches wide and eighty inches from the top end 16 to the bottom end 17 of mattress 10. Zoned foam layer 12 includes longitudinally spaced, transversely extending lateral regions 18-21 of foam. A first lateral region 18 is located at top end 16 of mattress 10. A second lateral region 19 is disposed between first lateral region 18 and a third lateral region 20. The user of mattress 10 sleeps with his or her shoulders over second lateral region 19 and his or her hips above a fourth lateral region 21. Regions 19 and 21 have a lower ILD than do regions 18 and 20. Consequently, the user's shoulders and hips sink deeper into regions 19 and 21.
However, forming a mattress by gluing together lateral blocks of foam having different degrees of hardness complicates the manufacturing process and adds to the cost of the mattress. In addition, the many glued joints create more places for the mattress to come apart. A method is sought for making a zoned foam mattress that does not require gluing together lateral rectangular blocks of foam to form the zones of different hardness.
A symmetrical zoned foam mattress includes an upper foam layer with a wavy lower side and a lower foam layer with a wavy upper side. The foam of the upper layer is softer than the foam of the lower layer. For example, the upper layer is made of softer memory foam, and the lower layer is made of harder high density foam (HD foam). The lower foam layer has a top, middle and bottom lateral valleys. The wavy lower side of the upper foam layer is glued to the wavy upper side of the lower foam layer. The upper foam layer together with the lower foam layer have a combined thickness that remains constant from the top head side to the bottom foot side of the mattress. The top lateral valley has a minimum located within eighteen inches of the top head end of the lower foam layer. The bottom lateral valley has a minimum located within eighteen inches of the bottom foot end of the lower foam layer. A center plane intersects the lower foam layer at a minimum of the middle lateral valley. The minimum of each of the top and bottom lateral valleys is about fifteen inches from the end of the mattress regardless of whether the consumer chooses to use the top or bottom end as the head of the mattress.
A cross section of the wavy upper side of the lower foam layer forms a curve that is a mirror image of itself on either side of a center plane through the lower foam layer. Thus, the top lateral valley and the bottom lateral valley are disposed symmetrically to the center plane. Between the top lateral valley and the middle lateral valley, the lower foam layer has a top lateral hill with a maximum located within eighteen inches of the center plane. The zoned foam mattress has a lower indentation load deflection (ILD) above the top lateral valley than above other regions immediately adjacent to the top lateral valley. Thus, the memory foam of the top layer above the top lateral valley of the lower layer imparts an ILD to the mattress above the top lateral valley that allows a person's shoulders to sink into the mattress so as to keep the person's spine straight.
A method of making a symmetrical zoned mattress with wavy upper and lower foam layers includes cutting first and second slabs along a predetermined curve. The first slab is made of harder foam than the second slab. For example, the first slab is made of HD foam, and the second slab is made of memory foam. The first slab of foam is cut to form a first top lateral valley, a first top lateral hill and a middle lateral valley in an upper side of a first foam layer. Cutting the first slab forms a top piece and a bottom piece. The bottom piece includes the first top lateral valley and the first top lateral hill. The top piece has a first bottom lateral valley.
The first foam layer is formed by attaching the bottom piece to the top piece at the minimum of the middle lateral valley. The first top lateral valley and the first bottom lateral valley are disposed symmetrically to a center plane of the first foam layer that intersects the upper side of the first foam layer at the minimum of the middle lateral valley. The minimum of the first top lateral valley is located within eighteen inches of the top head side of the first foam layer. In addition, the second slab of foam is cut to form a second top lateral hill, a second top lateral valley and a middle lateral hill in a lower side of a second foam layer.
The lower side of the second foam layer is then placed over the upper side of the first foam layer such that the second top lateral hill fits into the first top lateral valley, and the middle lateral hill fits into the middle lateral valley. The first foam layer together with the second foam layer have a combined thickness that is constant. The first top lateral valley has a minimum located within eighteen inches from a maximum of the first top lateral hill. An indentation load deflection (ILD) above the top lateral valley is lower than above other lateral regions immediately adjacent to the top lateral valley after the lower side of the second foam layer is placed over the upper side of the first foam layer.
Further details and embodiments are described in the detailed description below. This summary does not purport to define the invention. The invention is defined by the claims.
The accompanying drawings illustrate embodiments of the invention.
One method of making zoned foam mattress 22 involves forming lower layer 24 in a mold whose lid produces the shape of the wavy upper side of lower layer 24. The lid is then removed from the cured lower layer 24, and a softer foam is poured over lower layer 24 to form upper layer 23 with a planar upper surface. But molding individual foam layers of mattress 22 is time consuming and therefore costly. A mattress with wavy foam layers is sought that can be manufactured in a more efficient manner.
In another embodiment, lower foam layer 32 is formed from natural latex rubber (as opposed to HD foam) that also is harder than the memory foam used in the mattress. Wavy lower side 33 of upper foam layer 31 is adjacent to wavy upper side 34 of lower foam layer 32. Mattress 30 has a top portion 35, a middle portion 36 and a bottom portion 37. In
Center plane 41 intersects lower foam layer 32 at a minimum 53 of middle lateral valley 44. The cross section of wavy upper side 34 follows curve 42, as does the cross section of wavy lower side 33. Upper foam layer 31 together with lower foam layer 32 have a combined thickness that remains constant from the top 39 to the bottom 40 of mattress 39. The portion of curve 42 extending from center plane 41 towards the top 39 of mattress 30 is a mirror image of the portion of curve 42 extending from center plane 41 towards the bottom 40 of mattress 30. Thus, top lateral valley 43 and bottom lateral valley 45 are disposed symmetrically relative to center plane 41. The memory foam above first top lateral valley 43 of lower foam layer 32 imparts an indentation load deflection (ILD) to the lateral region above top lateral valley 43 that allows the shoulders of user 25 to sink into mattress 30 so as to keep the user's spine straight. Thus, mattress 30 has a lower ILD above top lateral valley 43 than above other regions immediately adjacent to top lateral valley 43. Similarly, the hips of user 25 resting on the greater thickness of softer foam at middle lateral valley 44 sink into mattress 30 more than does the user's torso. The user's spine can remain straighter if both the user's hips and shoulders sink farther into the mattress than do the user's torso and legs.
Mattress 30 is configured to provide optimum support for the largest percentage of North American consumers. The region 58 of the first top lateral valley 43 is about ten inches wide. In addition, region 58 of valley 43 is about ten inches from the top 39 of mattress 30. There are also about ten inches between region 58 of valley 43 and the region of middle lateral valley 44. The average consumer, regardless of body height, sleeps with his or her head the same distance from the top of the mattress. Thus, the average North American consumer sleeps with his or her shoulders about fifteen inches from the top of the mattress. The middles of lateral valleys 43 and 45 are both about fifteen inches from the “head” of mattress 20 regardless of whether user 25 chooses to use the top 39 or the bottom 40 as the head of the mattress. By placing two symmetrical lateral valleys 43 and 45 at the top 39 and bottom 40 of mattress 30, user 25 cannot lay the mattress down on a bed frame in the incorrect orientation with the head of the mattress towards the foot of the bed frame. Regardless of how the mattress is laid down on the bed, the valleys of softer foam for the shoulders are present without fail within the correct area of the mattress to contact the user's shoulders. The region of middle lateral valley 44 occupies the entire length of mattress 30 from thirty inches from the top 39 to thirty inches from the bottom 40 of the mattress. Thus, for a 75-inch long twin size mattress, the region of valley 44 is about fifteen inches long. For an 80-inch long queen size mattress, the region of valley 44 is about twenty inches long.
Mattress 30 does not have a zone of the wavy foam layers that is specifically tailored to the legs of a person reclining on the mattress. Instead, a user's legs lie over the regions of the lateral valleys 43 or 45 positioned for the shoulders. The benefit of always positioning a user's shoulders correctly over the region of a lateral valley, regardless of whether the user lies toward the top 39 or bottom 40 of mattress 30, outweighs the lack of optimum leg support. Providing a foam zone with an indentation load deflection (ILD) specifically suited to support a user's legs contributes much less to keeping the reclining user's spine straight than does positioning lateral regions with the appropriate ILDs beneath the user's shoulders and hips. Moreover, foam zones intended to support the legs are often ineffective. Where a tall man and a short woman are lying on the same mattress, their shoulders will likely rest at the same distance from the end of the mattress, whereas their legs will likely not rest in the same lateral region. Thus, any foam zone with an ILD specifically suited to support a user's legs would not be in the appropriate position for both the tall man and the short woman. Instead of offering multiple ineffective indentation zones, mattress 30 provides a shoulder foam zone that is always correctly positioned and a variable width hip foam zone that is appropriate for the largest percentage of North American consumers.
In a first step 61, first slab 68 is cut to form first top lateral valley 43, first top lateral hill 48 and middle lateral valley 44 in wavy upper side 34. The cut 70 in first slab 68 forms a bottom piece 71 and a top piece 72. First top lateral valley 43 and first top lateral hill 48 are on bottom piece 71. Top piece 72 has a first bottom lateral valley 73.
In step 62, lower foam layer 32 is formed by attaching bottom piece 71 to top piece 72 at minimum 53 of middle lateral valley 44 as shown in step (e) of
In step 63, second slab 69 is cut to form second top lateral hill 50, second top lateral valley 52 and middle lateral hill 51 in wavy lower side 33 of upper foam layer 31. The cut 75 in second slab 69 forms a top piece 76 and a bottom piece 77. Cut 75 has the same shape as cut 70. Second top lateral hill 50 and second top lateral valley 52 are on top piece 76. Bottom piece 77 has a second bottom lateral hill 78.
In step 64, upper foam layer 31 is formed by attaching top piece 76 to bottom piece 77 at a maximum 79 of middle lateral hill 51 as shown in step (e) of
In step 65, lower side 33 of upper foam layer 31 is placed over upper side 34 of lower foam layer 32 such that second top lateral hill 50 fits into first top lateral valley 43, and middle lateral hill 51 fits into middle lateral valley 44. First top lateral valley 43 has a minimum 46 located within eighteen inches from maximum 49 of first top lateral hill 48. Upper foam layer 31 is attached to lower foam layer 32 by gluing 81. After upper foam layer 31 is attached to lower foam layer 32, upper foam layer 31 together with lower foam layer 32 have a combined thickness that is constant, as shown in step (f) of
Two long foam sheets are used: one made of HD foam 83 and the other made of memory foam 84. The HD foam 83 is used to make lower foam layer 32, and the memory foam 84 is used to make upper foam layer 31. The foam sheets need not have the same thickness as shown in
The two long foam sheets of HD foam 83 and memory foam 84 are cut into four wavy layers, designated as 85, 86, 87, 88 in
In a second embodiment, the wavy layers 85-88 are first cut and then placed over each other. Lower wavy foam layer 85 is cut to form a first planar top side 89 that is approximately forty inches from middle lateral valley 44. Lower wavy foam layer 86 is cut in the same manner. Thus, middle lateral valley 44 is in the middle of each 80-inch segment of foam layers 85-86, as shown in
Cutting lower wavy foam layer 85 to form first planar top side 89 also forms a first planar bottom side 91 of the adjacent 80-inch segment to the right in
By cutting the sheets of foam along curve 42, each segment and also each mattress has lateral wavy foam zones that are symmetrical from top to bottom. This prevents the user 25 from placing the head side of the mattress at the foot of the bed, which would be possible if the curve of the wavy foam zones was not symmetrical with respect to the middle of the mattress. Cutting the sheets of foam along curve 42 also provides wavy foam zones in the correct position for the body zones of the largest segment of North American users. Regardless of body height, the average North American consumer sleeps with his or her shoulders about fifteen inches from the top of the mattress, which falls at the maximum of second top lateral hill 50 of the upper layer 31 of memory foam.
Although certain specific embodiments are described above for instructional purposes, the teachings of this patent document have general applicability and are not limited to the specific embodiments described above. Although a particular curve 42 is cut into the long sheets of foam to make mattress 30 as shown in
Number | Name | Date | Kind |
---|---|---|---|
951682 | Etter | Mar 1910 | A |
2469084 | Schenker | May 1949 | A |
3026544 | Persicke et al. | Mar 1962 | A |
3222697 | Scheermesser | Dec 1965 | A |
3319274 | Upton | May 1967 | A |
3885258 | Regan | May 1975 | A |
4229847 | Degen | Oct 1980 | A |
4628557 | Murphy | Dec 1986 | A |
4644593 | O'Brien | Feb 1987 | A |
4665573 | Fiore | May 1987 | A |
4673452 | Awdhan | Jun 1987 | A |
4980936 | Frickland et al. | Jan 1991 | A |
5048136 | Popitz | Sep 1991 | A |
6807698 | Torbet et al. | Oct 2004 | B2 |
20030221262 | Torbet | Dec 2003 | A1 |
20050115003 | Torbet | Jun 2005 | A1 |
20050193497 | Baker | Sep 2005 | A1 |
20060260060 | Apperson et al. | Nov 2006 | A1 |
20080060139 | Mossbeck | Mar 2008 | A1 |
20100264571 | Tarazona De La Asuncion | Oct 2010 | A1 |
20110056025 | Jew et al. | Mar 2011 | A1 |
20110283461 | Rasmussen | Nov 2011 | A1 |
20120124753 | Lee | May 2012 | A1 |
20140013505 | Sportis | Jan 2014 | A1 |
Number | Date | Country |
---|---|---|
804094 | Nov 1958 | GB |
Entry |
---|
http://www.pfa.org/jifsg/jifsgs4.html, Polyurethane Foam Association, Joint Industry Foam Standards and Guidelines, Published Jul. 1994. |
Marketing material for Harmony mattress from Wellness Schlafen Gesundheit GmbH, Voecklamarkt, Austria downloaded from www.welinesstower.com on Feb. 28, 2013 (3 pages). |
Number | Date | Country | |
---|---|---|---|
20140237728 A1 | Aug 2014 | US |