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ELASTIC MATTRESS CUSTOMIZED BY PARTITIONING SOFTNESS AND HARDNESS

20250248534 ยท 2025-08-07

    Inventors

    Cpc classification

    International classification

    Abstract

    An elastic mattress partitioning softness and hardness comprises at least two groups of spring modules with different elasticities and hardnesses. An inner side of each of the spring modules comprises a plurality of spring members that are spliced together, and each of the at least two groups of the spring modules comprises the plurality of spring members with at least one elasticity and hardness. Each of the spring modules defines an interlaced or array arrangement by the plurality of spring members through the connecting structures, and the spring modules with the different hardnesses in the elastic mattress are assembled in any section in the elastic mattress. A hardness of one or more of the plurality of spring members disposed in an edge section of the elastic mattress is greater than a hardness of one or more of the plurality of spring members in another section of the elastic mattress.

    Claims

    1. An elastic mattress customized by partitioning softness and hardness, comprising: at least two groups of spring modules with different elasticities and hardnesses, wherein: each of the spring modules comprise a plurality of spring members that are spliced together, an inner side of each of the at least two groups of the spring modules comprises the plurality of spring members with at least one elasticity and hardness, the plurality of spring members are disposed with connecting structures, the plurality of spring members are connected by the connecting structures or are connected by the connecting structures through one or more third connecting members, each of the spring modules defines an interlaced or array arrangement by the plurality of spring members through the connecting structures, the spring modules with the different hardnesses in the elastic mattress are configured to be assembled in any section in the elastic mattress by the connecting structures or the one or more third connecting members, and a hardness of one or more of the plurality of spring members disposed in an edge section of the elastic mattress is greater than a hardness of one or more of the plurality of spring members in another section of the elastic mattress other than the edge section.

    2. The elastic mattress customized by partitioning softness and hardness according to claim 1, wherein: the connecting structures are parts of the plurality of spring members or are connecting members assembled around the plurality of spring members, and multiple of the connecting structures between the plurality of spring members are configured to be connected together or be buckled through the one or more third connecting members.

    3. The elastic mattress customized by partitioning softness and hardness according to claim 1, wherein: the connecting structures are configured to have one or more fastening positions and one or more fastening points, and one of the one or more fastening positions on one of the connecting structures and one of the one or more fastening points on another one of the connecting structures form a releasable buckled connection.

    4. The elastic mattress customized by partitioning softness and hardness according to claim 1, wherein: one of the one or more third connecting members or the connecting structures comprises one or more fastening positions, the other one of the one or more third connecting members or the connecting structures comprises one or more fastening points, and the one or more fastening positions and the one or more fastening points form a releasable buckled connection.

    5. The elastic mattress customized by partitioning softness and hardness according to claim 3, wherein: the one or more fastening positions comprise one or more protrusions, the one or more fastening points comprise one or more grooves, the one or more protrusions have elasticities, and the one or more fastening positions or the one or more fastening points are disposed with one or more releasing members configured to push the one or more protrusions.

    6. The elastic mattress customized by partitioning softness and hardness according to claim 3, wherein: the one or more fastening positions comprise one or more protrusions, the one or more fastening points comprise one or more grooves, one or more rotating members are disposed on the one or more protrusions or the one or more grooves, and when the one or more fastening positions are disposed in the one or more fastening points, the one or more rotating members rotate to lock the one or more fastening positions on the one or more fastening points.

    7. The elastic mattress customized by partitioning softness and hardness according to claim 3, wherein: the one or more fastening positions comprise one or more protrusions, the one or more fastening points comprise one or more grooves, the one or more fastening points comprise one or more sliding members, and when the one or more fastening positions are disposed in the one or more fastening points, the one or more sliding members slide to lock the one or more fastening positions.

    8. The elastic mattress customized by partitioning softness and hardness according to claim 4, wherein: two ends of the one or more third connecting members respectively comprise buckling positions and engaging positions, and tails and heads of multiple of the one or more third connecting members form the releasable buckled connection through the buckling positions and the engaging positions.

    9. The elastic mattress customized by partitioning softness and hardness according to claim 1, wherein: a hardness of at least one supporting end of individuals of the plurality of spring members is configured to be adjusted, or hardnesses of upper and lower supporting ends of individuals of the plurality of spring members are configured to be equal to or not equal.

    10. The elastic mattress customized by partitioning softness and hardness according to claim 1, wherein: a soft pad layer is disposed on a top of the elastic mattress, all sides of the soft pad layer comprise surrounding edges or pulling straps, and the surrounding edges or the pulling straps are releasably connected to the connecting structures on an outer perimeter of the spring modules.

    11. The elastic mattress customized by partitioning softness and hardness according to claim 4, wherein: two ends of the one or more third connecting members respectively comprise fastening points and fastening positions, and tails and heads of multiple of the one or more third connecting members form the releasable buckled connection through the fastening points and the fastening positions.

    12. The elastic mattress customized by partitioning softness and hardness according to claim 1, wherein the hardness of each of the one or more of the plurality of spring members disposed in the edge section of the elastic mattress is greater than hardnesses of a remaining portion of the plurality of spring members in all other sections of the elastic mattress other than the edge section.

    Description

    BRIEF DESCRIPTION OF THE DRAWINGS

    [0021] FIG. 1 is a structural diagrammatic view of spring modules or one or more groups of the spring modules with different hardnesses in Embodiment 1;

    [0022] FIGS. 2-5 are structural diagrammatic views of elastic mattresses with different softnesses and hardnesses spliced by the one or more groups of the spring modules with the different hardnesses in Embodiment 1;

    [0023] FIG. 6 is a perspective view of the elastic mattress spliced by the one or more groups of the spring modules with the different hardnesses in Embodiment 1;

    [0024] FIG. 7 is a dissembled view of a soft pad and the elastic mattress spliced by the one or more groups of the spring modules with the different hardnesses in Embodiment 1;

    [0025] FIG. 8 is a structural diagrammatic view of a single spring member of a plurality of spring members in Embodiment 2;

    [0026] FIG. 9 is a structural diagrammatic view of a connection of two connecting structures of a plurality of connecting structures in Embodiment 2;

    [0027] FIG. 10 is a structural diagrammatic view of one of the plurality of connecting structures in Embodiment 2;

    [0028] FIG. 11 is a structural diagrammatic view of a spring module connected by the plurality of spring members in Embodiment 2;

    [0029] FIG. 12 is a structural diagrammatic view of a single spring member of a plurality of spring members in Embodiment 3;

    [0030] FIG. 13 is a structural diagrammatic view of a connection of two connecting structures of a plurality of connecting structures in Embodiment 3;

    [0031] FIG. 14 is a structural diagrammatic view of one of the plurality of connecting structures in Embodiment 3;

    [0032] FIG. 15 is a structural diagrammatic view of a spring module connected by the plurality of spring members in Embodiment 3;

    [0033] FIG. 16 is a structural diagrammatic view of a single spring member of a plurality of spring members in Embodiment 4;

    [0034] FIG. 17 is a structural diagrammatic view of one of the plurality of connecting structures in Embodiment 4;

    [0035] FIG. 18 is a structural diagrammatic view of a connection of the plurality of connecting structures in Embodiment 4;

    [0036] FIG. 19 is a structural diagrammatic view of a third connecting member in Embodiment 4;

    [0037] FIG. 20 is a structural diagrammatic view of a spring module connected by the plurality of spring members in Embodiment 4;

    [0038] FIG. 21 is a structural diagrammatic view of a single spring member in Embodiment 5;

    [0039] FIG. 22 is a structural diagrammatic view of one of a plurality of connecting structures in Embodiment 5;

    [0040] FIG. 23 is a structural diagrammatic view of a connection of two connecting structures of the plurality of connecting structures in Embodiment 5;

    [0041] FIG. 24 is a structural diagrammatic view of a connection of two spring members in Embodiment 6;

    [0042] FIG. 25 is a structural diagrammatic view of a connection of a plurality of connecting structures in Embodiment 6;

    [0043] FIG. 26 is a structural diagrammatic view of a fastening point of the plurality of connecting structures in Embodiment 6;

    [0044] FIG. 27 is a structural diagrammatic view of a fastening position of the plurality of connecting structures in Embodiment 6;

    [0045] FIG. 28 is a diagrammatic view of a connection of the fastening point and the fastening position of the plurality of connecting structures in Embodiment 6;

    [0046] FIG. 29 is a structural diagrammatic view of a single spring member in Embodiment 7;

    [0047] FIG. 30 is a structural diagrammatic view of one of a plurality of connecting structures in Embodiment 7;

    [0048] FIG. 31 is a structural diagrammatic view of a connection of the plurality of connecting structures in Embodiment 7;

    [0049] FIG. 32 is a diagrammatic view of a connection of a fastening point and a fastening position of the plurality of connecting structures in Embodiment 7;

    [0050] FIG. 33 is a structural diagrammatic view of a single spring member in Embodiment 8;

    [0051] FIG. 34 is a structural diagrammatic view of one of a plurality of connecting structures in Embodiment 8;

    [0052] FIG. 35 is a structural diagrammatic view of a connection of the plurality of connecting structures in Embodiment 8;

    [0053] FIG. 36 is a structural diagrammatic view of a connection in a spring module using third connecting members in Embodiment 9;

    [0054] FIG. 37 is a structural diagrammatic view of one of the third connecting members in Embodiment 9;

    [0055] FIG. 38 is an enlarged view of a connection structure of the third connecting members in Embodiment 9;

    [0056] FIG. 39 is a diagrammatic view of a connection of two of the third connecting members in Embodiment 9;

    [0057] FIG. 40 is a diagrammatic view of a connection of the third connecting members and one of a plurality of spring members in Embodiment 9;

    [0058] FIG. 41 is a diagrammatic view of a connection cooperation of a fastening position and a fastening point in Embodiment 9;

    [0059] FIG. 42 is a diagrammatic view of a row of the third connecting members assembled to the plurality of spring members in Embodiment 9;

    [0060] FIG. 43 is a structural diagrammatic view of two sides of a single spring member of the plurality of spring members connected to the third connecting members in Embodiment 9;

    [0061] FIG. 44 is a diagrammatic view of the plurality of spring members connected by the third connecting members in Embodiment 9;

    [0062] FIG. 45 is a structural diagrammatic view of a single spring member of spring members in Embodiment 10;

    [0063] FIG. 46 is a structural diagrammatic view of one of third connecting members in Embodiment 10;

    [0064] FIG. 47 is a diagrammatic view of a connection of two of the third connecting members in Embodiment 10;

    [0065] FIG. 48 is a diagrammatic view of a connection of the third connecting members and one of the spring members in Embodiment 10;

    [0066] FIG. 49 is a diagrammatic view of a connection cooperation of a fastening position and a fastening point in Embodiment 10;

    [0067] FIG. 50 is a diagrammatic view of a row of the third connecting members assembled to the spring members in Embodiment 10;

    [0068] FIG. 51 is a structural diagrammatic view of a single spring member of spring members in Embodiment 11;

    [0069] FIG. 52 is a structural diagrammatic view of one of third connecting members in Embodiment 11;

    [0070] FIG. 53 is a diagrammatic view of a connection of two of the third connecting members in Embodiment 11;

    [0071] FIG. 54 is a diagrammatic view of a connection of the third connecting members and one of the spring members in Embodiment 11;

    [0072] FIG. 55 is a diagrammatic view of a connection cooperation of a fastening position and a fastening point in Embodiment 11;

    [0073] FIG. 56 is a diagrammatic view of a connection of the fastening position and the fastening point that is locked to or unlocked in Embodiment 11;

    [0074] FIG. 57 is a diagrammatic view of a row of the third connecting members assembled to the spring members in Embodiment 11;

    [0075] FIG. 58 is a structural diagrammatic view of a single spring member of spring members in Embodiment 12;

    [0076] FIG. 59 is a structural diagrammatic view of one of third connecting members in Embodiment 12;

    [0077] FIG. 60 is a diagrammatic view of a connection of the one of the third connecting members and the spring members in Embodiment 12;

    [0078] FIG. 61 is a diagrammatic view of a row of the third connecting members assembled to the spring members in Embodiment 12; and

    [0079] FIG. 62 is a diagrammatic view of multiple rows of the third connecting members assembled to the spring members in Embodiment 12.

    [0080] Reference numerals in the accompanying drawings: spring member 1; connecting structure 2; fastening position 21; protrusion 211; protruding block 212; annular groove 213; buckling member 214; rotating member 215; fastening point 22; groove 221; groove opening 222; opening 223; buckling hole 224; sliding groove 225; releasing member 23; button 231; chamber 24; rotation member 25; annular opening 251; sliding member 26; insertion port 261; locking port 262; third connecting member 3; position-limited structure 31; buckling position 32; engaging position 33; spring module 4; elastic mattress 5; and soft pad layer 6.

    DETAILED DESCRIPTION OF THE EMBODIMENTS

    [0081] The technical solutions in the embodiments of the present disclosure will be described clearly and completely in combination with the accompanying drawings in the embodiments of the present disclosure. It is obvious that the described embodiments are merely some of the embodiments of the present disclosure rather than all of the embodiments, and all other embodiments fall within the protection scope of the present disclosure provided that they are obtained based on the embodiments of the present disclosure by a person of ordinary skill in the art without creative works.

    [0082] In the description of the present disclosure, it should be noted that terms, such as upper, lower, inner, outer, top, and bottom, indicate orientations or positional relationships based on orientations or positional relationships shown in the accompanying drawings, are merely used to easily describe the present disclosure and simplify the description of the present disclosure, rather than indicating or implying that a referenced device or element should have a particular orientation or be constructed and operated with a particular orientation, and therefore should not to be understood as a limitation of the present disclosure. Furthermore, the terms first and second are merely used for descriptive purposes and should not be understood as indicating or implying relative importance.

    [0083] In the description of the present disclosure, unless otherwise expressly specified and limited, it is noted that terms, such as mounted, provided with, socketed, sleeved, and connected, should develop a broad understanding, for example, connection can be a wall-mountable connection, a detachable connection, an integrated connection, a mechanical connection, an electrical connection, a direct connection, an indirect connection via an intermediate medium, or a communication between inner portions of two elements, and the specific meaning of the terms in the present disclosure can be understood in specific conditions for those of ordinary skill in the art.

    [0084] Referring to FIGS. 1-62, these embodiments provide an elastic mattress customized by partitioning softness and hardness, and the elastic mattress 5 comprises multiple groups of spring modules 4 with different hardnesses. Each of the plurality of spring modules 4 is formed by splicing a plurality of spring members 1, and the plurality of spring members 1 are pre-compressed springs. The hardnesses are preset initial compression forces of springs in the plurality of spring members 1. The multiple groups of the spring modules 4 comprise at least two groups of the spring modules 4 with different elasticities and hardnesses. An inner side of a group of the at least two groups of the spring modules 4 comprises the plurality of spring members 1 with at least one hardness. The plurality of spring members 1 are disposed with connecting structures 2, and the plurality of spring members 1 are connected by the connecting structures 2 or are connected by the connecting structures 2 through third connecting members 3. Each of the plurality of spring modules 4 is an interlaced or array arrangement of the plurality of spring members 1 through the connecting structures 2. The plurality of spring modules 4 with the different hardnesses in the elastic mattress 5 are configured to be assembled in any section in the elastic mattress 5 by the connecting structures 2 or the third connecting members 3. A hardness of one or more of the plurality of spring members 1 disposed in an edge section of the elastic mattress 5 is greater than a hardness of one or more of the plurality of spring members 1 in sections of the elastic mattress 5 other than the edge section.

    [0085] In this embodiment, hardnesses of the involved plurality of spring members 1 with different hardnesses can be adjusted by selecting the plurality of spring members 1 with preset different hardnesses. Individuals of the plurality of spring members 1 are configured such that hardnesses of upper and lower supporting ends are equal or not equal. Alternatively, a hardness of at least one of the upper or lower supporting ends of the individuals of the plurality of spring members 1 is adjustable, and the at least one of the upper and lower supporting ends is disposed with an adjustment device. The adjustment device is configured to adjust the preset initial compression forces of the springs in the plurality of spring members 1, thereby altering the hardnesses of the plurality of spring members 1.

    [0086] Specifically, the individuals of the plurality of spring members 1 comprise supporting sleeves and the springs sleeved in the supporting sleeves, and the supporting sleeves enable the springs to be in a state of the preset initial compression forces. Supporting ends of the supporting sleeves are disposed with spring preload devices, and the spring preload devices are disposed on elastic compression ends of the springs. The spring preload devices are configured to adjust the preset initial compression forces of the springs. The supporting sleeves are configured to enable the springs to have the preset initial compression forces, and the spring preload devices can further press the springs downwardly to enable the springs to be further compressed to effectively increase the hardnesses of the springs based on the preset initial compression forces. The spring preload devices can be a spiral progressive structure, and the springs are gradually pressed down or the springs are released in a reverse direction by spiral movement. The compression forces of the springs based on the preset initial compression forces are adjusted.

    Embodiment 1

    [0087] In Embodiment 1, as shown in FIGS. 1-7, one of the plurality of spring modules 4 having the plurality of spring members 1 with three different hardnesses is provided.

    [0088] As shown in FIGS. 1-7, for example, the plurality of spring members 1 with the three different hardnesses in this embodiment comprise three spring structures with a first spring hardness A, a second spring hardness B, and a third spring hardness C. A hardness magnitude is as follows, the first spring hardness A is greater than the second spring hardness B, and the second spring hardness B is greater than the third spring hardness C. In a selection of hardnesses of the springs, for one or more of the plurality of spring members 1 disposed on an edge of the elastic mattress 5, the first spring hardness A having the largest hardness is adopted, and for a section in a middle of the elastic mattress 5 for lying, the second spring hardness B and the third spring hardness C that have smaller hardnesses are adopted. In addition, a hardness difference between the second spring hardness B and the third spring hardness C is not large. Thus, a certain hardness is maintained while satisfying softness, thereby adjusting to meet the requirement of the different hardnesses for the user.

    [0089] In this embodiment, the plurality of spring modules 4 are used as adjustment modules, and the plurality of spring modules 4 are spliced by the plurality of spring members 1 with the three different hardnesses to obtain the plurality of spring modules 4 with the different hardnesses. Splicing adjustment of the softness and the hardness of the plurality of spring members at any section can then be achieved by the one or more groups of the spring modules, and the one or more groups of the spring modules that genuinely adapts to different softness and hardness requirements are spliced and customized, and hardness variations at different positions or different sections are spliced according to the requirement of the user.

    [0090] For example, as shown in FIG. 1, in the formed elastic mattresses 5, most of head sections are assembled with pillows, and there are no excessive softness and hardness requirements for the one or more of the plurality of spring members 1 at the head sections. However, with respect to a waist section, people with lumbar issues prefer a touch with more obvious hardness. Therefore, in a section of the elastic mattress 5 corresponding to a waist of a human body, the plurality of spring members 1 with the second spring hardness B are used as a padding. At the same time, in order to match with a hardness of the waist section and an abdomen section and to avoid excessive pressure on the lumbar due to merely localized hardness at the waist when lying down, the plurality of spring members 1 with the same hardness are disposed on edges of the elastic mattress 5 corresponding to legs and feet. The plurality of spring members 1 with the third spring hardness C are used as a padding in other positions, providing better support for the waist and the legs of the human body when lying down, enhancing lying comfort of human and improving sleep quality.

    [0091] At the same time, in this embodiment, the plurality of spring members 1 with the spring hardness A are disposed along the edge of the elastic mattress 5 as a peripheral padding to provide a hardness requirement at the edge of the elastic mattress 5, preventing a collapse phenomenon at the edge caused by sitting for a long time.

    [0092] The disclosure should be not limited to the splicing method provided in this embodiment, alternatively, the elastic mattress 5 using the spring hardness C as a primary support is provided, as shown in FIG. 2. Alternatively, the elastic mattress 5 using the spring hardness B as a primary support is provided, as shown in FIG. 3. Alternatively, the elastic mattress 5 using the spring hardness B and the spring hardness C as a designated partition support is provided, as shown in FIG. 4. Alternatively, the elastic mattress 5 using the spring hardness B and the spring hardness C as a designated partition support is provided, and different partitions for a double-user configuration are further distinguished, as shown in FIG. 5.

    [0093] In this embodiment, a usage structure of the elastic mattress 5 is further provided, as shown in FIGS. 6-7. A soft pad layer 6 is disposed on an upper layer of the elastic mattress 5, and all sides of the soft pad layer 6 comprise short surrounding edges or short pulling straps. The short surrounding edges or the short pulling straps are disposed with connecting structures 2, which are the same as that of the plurality of spring modules 4 so as to form detachable connections with one or more of the connecting structures 2 on an outer periphery of the plurality of spring modules 4.

    [0094] In order to achieve a rapid assembly of the plurality of spring modules 4 and the soft pad layer 6 and to enable a nested integrated body to have better stability, specific structures of the connecting structures 2 between the plurality of spring members 1 are specifically provided below based on Embodiment 1, as shown in FIGS. 8-62.

    Embodiment 2

    [0095] As shown in FIGS. 8-11, a waist ring having multiple insertion functions as a connecting structure 2 of the connecting structures 2 is disposed around a periphery of one of the plurality of spring members 1. The connecting structure 2 comprises one or more fastening positions 21 and one or more fastening points 22 interlaced at equal intervals along a circumferential direction of the connecting structure 2 and releasably buckled together. The one or more fastening positions 21 comprise one or more protrusions 211, and the one or more fastening points 22 comprise one or more grooves 221. The one or more protrusions 211 have elasticities, and the one or more fastening points 22 are disposed with one or more releasing members 23 configured to push the elasticities of the one or more protrusions 211. The one or more fastening points 22 are disposed on two opposite sides of the connecting structure 2, and the one or more fastening positions 21 are disposed on another two opposite sides of the connecting structure 2.

    [0096] Specifically, the one or more protrusions 211 are disposed with one or more buckling structures configured to define a position-limited cooperation with the one or more grooves 221. The one or more buckling structures have elasticities, and the one or more releasing members 23 are disposed at one or more positions of one or more walls of the one or more grooves 221 corresponding to the one or more buckling structures. The one or more releasing members 23 are pressed to drive the one or more buckling structures to release the position-limited cooperation with the one or more grooves 221 to achieve a disassembly of the plurality of spring members 1.

    [0097] The one or more buckling structures are one or more protruding blocks 212 disposed on the one or more protrusions 211, and the one or more releasing members 23 are disposed on one or more upper walls of the one or more grooves 221. The one or more upper walls of the one or more grooves 221 comprise one or more spaces into which the one or more protruding blocks 212 are buckled, so as to achieve the position-limited cooperation between the one or more buckling structures and the one or more grooves 221.

    Embodiment 3

    [0098] As shown in FIGS. 12-15, a waist ring having multiple insertion functions as a connecting structure 2 of the connecting structures 2 is disposed around a periphery of one of the plurality of spring members 1. The connecting structure 2 comprises a plurality of chambers 24 disposed at equal intervals along a circumferential direction of the connecting structure 2, and one of the plurality of chambers 24 comprises a convex buckle (i.e., a fastening position 21) and a concave buckle (i.e., a fastening point 22) configured to be releasably buckled to each other. The one or more fastening positions 21 have one or more protrusions 211, and the fastening points 22 have one or more grooves 221. The one or more protrusions 211 have elasticities, and the one or more fastening positions 21 are disposed with one or more releasing members 23 configured to push the elasticities of the one or more protrusions 211.

    [0099] Specifically, the one or more protrusions 211 are disposed with one or more buckling structures configured to define a position-limited cooperation with the one or more grooves 221. The one or more buckling structures have elasticities. The one or more releasing members 23 are disposed on a side of the one or more protrusions 211 and are operatively coupled to the one or more protrusions 211. The one or more releasing members 23 are pressed to drive the one or more buckling structures to release the position-limited cooperation with the one or more grooves 221 to achieve a disassembly of the plurality of spring members 1.

    [0100] The one or more buckling structures are one or more protruding blocks 212 disposed on one or more side edges of the one or more protrusions 211, and the one or more releasing members 23 are disposed on the one or more side edges of the one or more protrusions 211 disposed with the one or more protruding blocks 212. One or more side walls of the one or more grooves 221 comprise one or more spaces into which the one or more protruding blocks 212 are buckled, so as to achieve the position-limited cooperation between the one or more buckling structures and the one or more grooves 221.

    Embodiment 4

    [0101] As shown in FIGS. 16-20, one of the connecting structures 2 is disposed on a periphery of one of the plurality of spring members 1, and the connecting structures 2 are configured to define a connection with one or more third connecting members 3. The connecting structures 2 are assembled around the plurality of spring members 1. The connecting structures 2 are configured to have a plurality of fastening positions 21, and the one or more third connecting members 3 are configured to have a plurality of fastening points 22. The plurality of fastening points 22 of one of the one or more third connecting members 3 can simultaneously form a releasable buckled connection with one of the plurality of fastening positions 21 on four of the connecting structures 2 of the plurality of spring members 1.

    [0102] The specific structure of the connecting structures 2 and the one or more third connecting members 3 is described as follows, the plurality of fastening positions 21 have protrusions 211, and the plurality of fastening points 22 have grooves 221. The plurality of fastening points 22 comprise rotation members 25 disposed on outer peripheries of the grooves 221. When the plurality of fastening positions 21 are disposed in the plurality of fastening points 22, the rotation members 25 rotate to lock the plurality of fastening positions 21.

    [0103] The plurality of fastening positions 21 comprise the protrusions 211 and annular grooves 213 extending from the protrusions 211 to bodies of the plurality of fastening points 22. The plurality of fastening points 22 comprise cavities for receiving the protrusions 211, groove openings 222 for receiving the annular grooves 213, and openings 223 in communication the cavities and the groove openings 222. The protrusions 211 enter into the cavities through the openings 223. Individuals of the rotation members 25 are sleeved around outer sides of the cavities, and the rotation members 25 comprise annular openings 251 matched with the openings 223. The rotation members 25 rotate to enable the openings 223 to be aligned or misaligned with the annular openings 251 so as to unlock or lock the protrusions 211.

    Embodiment 5

    [0104] As shown in FIGS. 21-23, a waist ring having multiple insertion functions as a connecting structure 2 of the connecting structures 2 is disposed around a periphery of one of the plurality of spring members 1. The connecting structure 2 comprises one or more fastening positions 21 and one or more fastening points 22 interlaced at equal intervals along a circumferential direction of the connecting structure 2 and releasably buckled together. The one or more fastening positions 21 comprise one or more protrusions 211, and the one or more fastening points 22 comprise one or more cavities for receiving the one or more protrusions 211 and openings 223. The one or more fastening points 22 comprise sliding members 26 disposed on one or more outer peripheries of the one or more cavities and configured to be pressed downward. When the one or more fastening positions 21 are disposed in the one or more fastening points 22, the one or more sliding members 26 slide to lock the one or more fastening positions 21.

    [0105] The one or more fastening positions 21 comprise the one or more protrusions 211 and one or more annular grooves 213 extending from the one or more protrusions 211 to bodies of the one or more fastening points, and the one or more protrusions 211 enter into the one or more cavities through the one or more openings 223. Individuals of the one or more sliding members 26 configured to be pressed downward are slidably assembled to one or more outer sides of the one or more cavities, and the one or more sliding members 26 comprise one or more insertion ports 261 that match with one or more sizes of the one or more openings 223 and one or more locking ports 262 that match with one or more diameters of the one or more annular grooves 213. The one or more insertion ports 261 are in communication with the one or more locking ports 262. The one or more sliding members 26 can slide up and down so that the one or more insertion ports 261 or the one or more locking ports 262 are alternatively aligned with the one or more openings 223 so as to unlock or lock the one or more protrusions 211.

    Embodiment 6

    [0106] As shown in FIGS. 24-28, a waist ring having multiple insertion functions as a connecting structure 2 of the connecting structures 2 is disposed around a periphery of one of the plurality of spring members 1. The connecting structures 2 disposed on the plurality of spring members 1 are divided into one or more first connecting structures 2 and one or more second connecting structures 2. The one or more first connecting structures 2 have a plurality of fastening points 22 disposed along a circumferential direction of the one or more first connecting structures 2, and the one or more second connecting structures 2 have a plurality of fastening positions 21 disposed along a circumferential direction of the one or more second connecting structures 2. Each of the plurality of fastening positions 21 has a protrusion 211, and each of the plurality of fastening points 22 has a buckling hole 224. Each of the plurality of fastening positions 21 has a rotating member 215 disposed on a lower end of the protrusion 211. Each of the plurality of fastening positions 21 is configured such that a corresponding one of the plurality of fastening positions 21 is locked in the buckling hole 224 by rotating the rotating member 215 when each of the plurality of fastening positions 21 is disposed in the buckling hole 224, and a portion of each of the plurality of fastening positions 21 disposed with the rotating member 215 passes through the buckling hole 224.

    [0107] The protrusion 211 of each of the plurality of fastening positions 21 comprises a buckling member 214 and the rotating member 215 configured to rotate relative to the buckling member 214. Each of the plurality of fastening points 22 comprises the buckling hole 224 configured to enable the buckling member 214 and the rotating member 215 to pass through. Each of the plurality of fastening positions 21 comprises the rotating member 215 and the buckling member 214 disposed in sequence along an insertion direction. The rotating member 215 can rotate relative to the buckling member 214 to be aligned or misaligned with the buckling member 214. The rotating member 215 and the buckling member 214 can be inserted into the buckling hole 224 in sequence when aligned. When the rotating member 215 continues to be inserted along the insertion direction until the rotating member 215 passes through the buckling hole 224 and is disposed on a lower end of the buckling hole 224, the rotating member 215 can rotate to be misaligned with the buckling hole 224 so as to lock the buckling member 214 in the buckling hole 224.

    Embodiment 7

    [0108] As shown in FIGS. 29-32, a waist ring having multiple insertion functions as a connecting structure 2 of the connecting structures 2 is disposed around a periphery of one of the plurality of spring members 1. The connecting structure 2 comprises one or more fastening positions 21 and one or more fastening points 22 interlaced at equal intervals along a circumferential direction of the connecting structure 2 and releasably buckled together. The one or more fastening positions 21 comprise one or more protrusions 211, and the one or more fastening points 22 comprise one or more grooves 221. The one or more protrusions 211 have elasticities, and the one or more fastening points 22 are disposed with one or more releasing members 23 configured to push the elasticities of the one or more protrusions 211. The one or more fastening points 22 are disposed on two opposite sides of the connecting structure 2, and the one or more fastening positions 21 are disposed on another two opposite sides of the connecting structure 2.

    [0109] Each of the one or more fastening positions 21 comprises a rectangular insertion member, and two protrusions 211 of the one or more protrusions 211 are disposed on two side walls of the rectangular insertion member. An end surface of each of the one or more fastening points 22 correspondingly comprises a sliding groove 225, and two grooves 221 of the one or more grooves 221 are disposed on two opposite sliding side walls inside of the sliding groove 225. When the rectangular insertion member slides inward along the two opposite sliding side walls of the sliding groove 225 and slides until the two protrusions 211 are aligned with the two grooves 221, the two protrusions 211 pop out and are buckled to the two grooves 221 to inhibit a sliding movement of the rectangular insertion member, thereby achieving a buckled connection and a fixation of the one or more fastening positions 21 and the one or more fastening points 22.

    [0110] Each of the one or more fastening points 22 is disposed with one or more buttons 231 disposed on the two grooves 221 as the one or more releasing members 23. The one or more buttons 231 are pressed inward to enable the two protrusions 211 to contract to release a buckled cooperation with the two grooves 221. When unlocking is required, the one or more buttons 231 are correspondingly pressed on both sides to enable the two protrusions 211 to contract to release the buckled connection.

    Embodiment 8

    [0111] As shown in FIGS. 33-35, similar to Embodiment 2, Embodiment 8 also comprises one or more fastening positions 21 and one or more fastening points 22 interlaced at equal intervals along a circumferential direction of the connecting structure 2 and releasably buckled together. The one or more fastening positions 21 comprise one or more protrusions 211, and the one or more fastening points 22 comprise one or more grooves 221. The one or more protrusions 211 have elasticities, and the one or more fastening points 22 are disposed with one or more releasing members 23 configured to push the elasticities of the one or more protrusions 211.

    [0112] The one or more protrusions 211 are disposed with one or more buckling structures (i.e., one or more protruding block 212) configured to define a position-limited cooperation with the one or more grooves 221. The one or more buckling structures have elasticities, and the one or more releasing members 23 are disposed on one or more positions of one or more walls of the one or more grooves 221 corresponding to the one or more buckling structures. The one or more releasing members 23 are pressed to drive the one or more buckling structures to release the position-limited cooperation with the one or more grooves 221 to achieve a disassembly of the plurality of spring members 1.

    [0113] As an optimized structure, one or more buttons 231 are used as the one or more releasing members 23, so that an appearance of a connection of the connecting structures 2 is more beautiful and natural.

    Embodiment 9

    [0114] As shown in FIGS. 36-44, in this embodiment, the connecting structures are mainly connected by the one or more third connecting members 3. One of the connecting structures 2 is disposed on a periphery of one of the plurality of spring members 1, and the connecting structures 2 are configured to be connected by the one or more third connecting members 3. The connecting structures 2 are connecting members assembled around the plurality of spring members 1. Each of the connecting structures 2 is configured to have a plurality of fastening positions 21, and each of the one or more third connection members 3 is configured to have fastening points 22. The plurality of fastening positions 21 are disposed on two opposite side surfaces of each of the connecting structures 2, and the fastening points 22 are disposed on two opposite sides of each of the one or more third connecting members 3. A single side of the two opposite sides of each of the one or more third connecting members 3 is disposed with a single one of the fastening points 22.

    [0115] Each of the plurality of fastening positions 21 comprises a protrusion 211, and each of the fastening points 22 comprises a groove 221. A side wall of the groove 221 has elasticity. Each of the fastening points 22 is disposed with a releasing member 23 configured to push the elasticity of the side wall of the groove 221.

    [0116] Specifically, the protrusion 211 is disposed with a buckling structure (i.e., a protruding block 212) configured to define a position-limited cooperation with the groove 221. A side wall of the groove 221 has a position-limited structure 31 configured to define a position-limited cooperation with the buckling structure. The position-limited structure 31 has elasticity. The releasing member 23 is disposed on a side of the position-limited structure 31 and is operatively coupled to the position-limited structure 31. The releasing member 23 is pressed to drive the position-limited structure 31 to release the position-limited cooperation with the groove 221 to achieve a disassembly of the plurality of spring members 1.

    [0117] At the same time, two ends of each of the one or more third connecting members 3 respectively form buckling members configured to be buckled together. The buckling members comprise a buckling position 32 and an engaging position 33. The buckling position 32 of one of the one or more third connecting members 3 and the engaging position 33 of another one of the one or more third connecting members 3 form a releasable connection to form a row of the one or more third connecting members 3 for connecting the plurality of spring members 1.

    [0118] In this embodiment, there are two methods to connect the one or more third connecting members 3 and the plurality of spring members 1. In a first method, multiple of the one or more third connecting members 3 firstly form a long row of the one or more third connecting members 3 by a head-to-tail connection, and the fastening points 22 on the long row of the one or more third connecting members 3 are then respectively connected to the plurality of fastening positions 21 on the plurality of spring members 1 in sequence to form a corresponding one of the plurality of spring modules 4. The plurality of spring modules 4 are formed in rows, and then the fastening points 22 and the plurality of fastening positions 21 between the rows are connected to form the elastic mattress 5 (as shown in FIG. 42). In a second method, the fastening points 22 on the two opposite sides of an individual one of the one or more third connecting members 3 are firstly connected to the plurality of fastening positions 21 on the plurality of spring members 1 in sequence, and the plurality of spring members 1 are connected to form a correspond one of the plurality of spring modules 4 using a connection between the one or more third connecting members 3 and the connecting structures 2. The plurality of spring modules 4 are formed in rows, and the rows form the elastic mattress 5 by a head-to-tail connection of the buckling members disposed on the one or more third connecting member 3, as shown in FIGS. 43 and 44.

    Embodiment 10

    [0119] As shown in FIGS. 45-50, the one or more third connecting members 3 differ from the one or more third connecting members 3 in Embodiment 9. A design of the one or more third connecting members 3 in this embodiment differs from the one or more third connecting members 3 in Embodiment 9 in that a single side of the two opposite sides of each of the one or more third connecting members 3 is disposed with four fastening points 22 of the fastening points 22 and is not limited to the four fastening points 22.

    [0120] Based on the technology of Embodiment 9, an arrangement of the one or more third connecting members 3 is optimized, a number of parts of the one or more third connecting members 3 is simplified, allowing splicing of the one or more third connecting members 3 and splicing between the one or more third connecting members 3 and the plurality of spring members 1 to be faster.

    Embodiment 11

    [0121] As shown in FIGS. 51-57, in this embodiment, the connecting structures are mainly connected by the one or more third connecting members 3. A connecting structure of the connecting structures 2 are disposed on a periphery of one of the plurality of spring members 1, and the connecting structures 2 are configured to be connected by the one or more third connecting members 3. The connecting structures 2 are connecting members assembled around the plurality of spring members 1. One of two opposite side surfaces of each of the connecting structures 2 is configured to be disposed with one of fastening positions 21, and another of the two opposite sides of each of the connecting structures 2 is disposed with one of fastening points 22. The one or more third connecting members 3 are configured to have one or more of the fastening points 22, and the one or more third connecting members 3 comprises multiple of the fastening points 22 along a length direction of the one or more third connecting members 3.

    [0122] Each of the fastening positions 21 comprises a buckling member 214 and a rotating member 215 configured to rotate relative to the buckling member 214. Each of the fastening points 22 comprises a buckling hole 224 configured to enable the buckling member 214 and the rotating member 215 to pass through. The buckling member 214 can be sleeved into two of the buckling holes 224 at the same time in a height arrangement. Each of the fastening positions 21 comprises the rotating member 215 and the buckling member 214 disposed along an insertion direction in sequence. The rotating member 215 can rotate relative to the buckling member 214 to be aligned or misaligned with the buckling member 214. When the rotating member 215 is aligned with the buckling member 214, the rotating member 215 and the buckling member 214 can be inserted into the buckling hole 224 in sequence. When the rotating member 215 continues to be inserted along the insertion direction until the rotating member 215 passes through the buckling hole 224 and is located below the buckling hole 224, the rotating member 215 rotates to be misaligned with the buckling hole 224 so as to lock the buckling member 214 in the buckling hole 224.

    [0123] At the same time, a first end of two ends of each of the one or more third connecting members 3 is disposed with the fastening positions 21 the same as that of the connecting structures 2, and the second fastening position 21 is configured to be connected to the fastening points 22 located on a second end of the two ends of each of the one or more third connecting members 3. Multiple of the one or more third connecting members 3 are connected through the fastening positions 21 and the fastening points 22 to define a row of the one or more third connecting members 3 for connecting the plurality of spring members 1 together.

    [0124] A connection between the one or more third connecting members 3 and the plurality of spring members 1 is described as follow. With respect to a connection of two rows of the plurality of spring members 1, the fastening points 22 of a first row of the two rows of the plurality of spring members 1 and the fastening points 22 of the one or more third connecting members 3 are connected to the fastening positions 21 of a second row of the two rows of the plurality of spring members 1. As shown in FIG. 57, the plurality of spring members 1 in the formed elastic mattress 5 are disposed in an array arrangement.

    [0125] Alternatively, the one or more third connecting members 3 in this embodiment can be also applied to structures of the connecting structures of the plurality of spring members 1 similar to those in Embodiment 6 in which merely the one or more fastening positions 21 are disposed. Two opposite side surfaces of each of the plurality of spring members 1 are disposed with the fastening positions 21. With respect to a connection of the two rows of the plurality of spring members 1, the fastening positions 21 and the fastening points 22 of the one or more third connecting members 3 form an interlaced connection, and the plurality of spring members 1 in the formed elastic mattress 5 are disposed in an interlaced arrangement.

    Embodiment 12

    [0126] As shown in FIGS. 58-62, in this embodiment, the connecting structures 2 are mainly connected by the one or more third connecting members 3. A connecting structure 2 of the connecting structures 2 is disposed on a periphery of one of the plurality of spring members 1, and the connecting structures 2 are configured to be connected by the one or more third connecting members 3. The connecting structures 2 are connecting members assembled around the plurality of spring members 1. Two opposite side surfaces of each of the connecting structures 2 are disposed with fastening positions 21. Two opposite sides of each of the one or more third connecting members 3 are disposed with fastening points 22, and the one or more third connecting members 3 have multiple of the fastening points 22 along a length direction of the one or more third connecting members 3. Each of the fastening positions 21 has a protrusion 211, and each of the fastening points 22 has a groove 221. The protrusion 211 has elasticity. Each of the fastening positions 21 is disposed with a releasing member 23 configured to push the protrusion 211.

    [0127] Specifically, the protrusion 211 is disposed with a buckling structure configured to cooperate with the groove 221. The buckling structure has elasticity, and the releasing member 23 is disposed on a side of the protrusion 211 and is operatively coupled to the protrusion 211. The releasing member 23 is pressed to drive the buckling structure to release a position-limited cooperation with the groove 221 to achieve a disassembly of the plurality of spring members 1.

    [0128] The buckling structure is a protruding block 212 disposed on an upper side of the protrusion 211, and the releasing member 23 is disposed on a side edge of the protrusion 211 disposed with the protruding block 212. An upper wall of the groove 221 comprises a space into which the protruding block 212 is buckled, so as to achieve the position-limited cooperation between the buckling structure and the groove 221.

    [0129] At the same time, two ends of each of the one or more third connecting members 3 are respectively formed with buckling members that are configured to be buckled to each other. The buckling members comprise a buckling position 32 and an engaging position 33. The buckling position 32 of one of the one or more third connecting members 3 and the engaging position 33 of another one of the one or more third connecting members 3 form a releasable connection to form a row of the one or more third connecting members 3 for connecting the plurality of spring members 1.

    [0130] In this embodiment, one end of each of the one or more third connecting members 3 comprises a structure configured to be connected to the soft pad layer 6. The structure connected to the soft pad layer 6 can be the same as a structure configured to be connected to plurality of spring members 1. The structure of each of the one or more third connecting members 3 configured to be connected to the soft pad layer 6 is also involved in the aforementioned other embodiments.

    [0131] The aforementioned description is merely preferred specific embodiments of the present disclosure, and the design and the concept of the present disclosure is not limited thereto. It is intended that the present disclosure cover any unsubstantial modifications of the present disclosure provided they are made without departing from the technical scope of the present disclosure based on the concept by person familiar with skill in the technical art.