The invention relates to a flexible member with adjustable stiffness for lying and/or sitting furniture. This member includes one or more inner spring(s) oriented along a central axis, one or more pair(s) of outer helical springs about the central axis, and a rotating part able to rotate, about the central axis, between a blocking position and an unblocking position. Each pair of outer helical springs includes an upper outer helical spring and a lower outer helical spring, connected by a corresponding hinge, which has a pivot axis orthogonal to the central axis. In the blocking position, the rails engage the corresponding hinges of the pairs of the outer helical spring, so as to prevent radial displacement, relative to the central axis, of the corresponding hinges, while the unblocking position allows the radial displacement of each corresponding hinge.

The proposed technology provides a spring compression arrangement (100) for a bed mattress (11). The spring compression arrangement (1) comprises a block (1) made of an elastic material, where the block comprises a first outer surface (12a) and an oppositely positioned, second outer surface (12b), the spring compression arrangement (1) further comprises a plurality of springs (2) provided in said block (1), said springs extending in a direction from said second outer surface (12b) to said first outer surface (12a). The proposed technology also provides a bed mattress comprising such a spring compression arrangement as well as a bed comprising bed mattress comprising such a spring compression arrangement. Also disclosed is a method for producing a spring compression arrangement according to the proposed technology.

A bed includes components to control pressure of a sleep surface, for example based on sleep position and sleep stages of a user. In some embodiments target pressures for the sleep surface are iteratively adjusted over multiple sleep sessions so to achieve improvements in sleep states and/or sleep quality for the user.

A cellular furniture construction system that includes: a set of voxels, that form a lattice providing the shape and structure of the furniture construction, wherein regions of the furniture construction comprise distinct three-dimensional lattice arrangements of different types of voxels, providing distinct stress/strain properties to the regions; wherein each voxel comprises: a voxel type, defined by the stress and strain property of the voxel, and a discrete cellular three-dimensional structure, enabled to connect with other voxels along any one of the voxel interface surfaces. The system functions as a lightweight, modular, furniture construction system, wherein the system leverages arrangements of different voxel types to construct a furniture structure with desired stress/strain properties to regions of the structure.

A firmness controlling apparatus for use in a bed arrangement or a seating arrangement is disclosed. The apparatus comprises a rigid frame having two opposed sides, and at least one non-elastic flexible elongate element extending between the two opposed sides. Each end of the non-elastic flexible elongate element is directly or indirectly connected to one of the opposed sides, and at least one of the ends is indirectly connected via an elastic flexible elongate element. A plurality of elongate springs are provided and extend in a flat or curved plane, the ends of each elongate spring being attached to one of the at least one non-elastic flexible elongate elements at two separated connections. A retraction device is arranged to tighten and slack the non-elastic flexible elongate element(s) between the two separated connections, thereby adjusting the distance between the two separated connections of each non-elastic flexible elongate element, and thereby controlling the curvature and height of the elongate springs.

Spring modules for an adjustable sleeping system. At least some of the example embodiments are spring modules comprising: a spring rail, and a plurality of adjustable spring assemblies spaced along the length of the spring rail. Each adjustable spring assembly may comprise: a motor with a stator coupled to the spring rail, a lead screw coupled to the rotor of the motor, and the lead screw extending above an upper surface of the spring rail, a spring plate coupled to the lead screw, and a main spring coupled to the spring plate. Thus, the weight or force carried by each adjustable spring assembly along the spring rail is separately adjustable by a bed controller.

The disclosure relates to a bunk, in particular for a vehicle cabin. The bunk comprises a base plate, an upper layer, a plurality of supporting members vertically compressible and spaced apart from one another substantially over the whole surface of the bunk, a plurality of pressure sensors which are part of the upper layer and in an adaptable area comprising at least one area of the bunk, a moving mechanism configured to move at least some of the supporting members in the adaptable area parallel to the base plate, and a control unit connected to the pressure sensors and the moving mechanism. The control unit is configured to cause the moving mechanism to move the supporting members in the adaptable area as a function of the current pressure data provided by the pressure sensors, to locally change the density of the supporting members to provide a locally variable bunk firmness.

A bed includes components to control pressure of a sleep surface, for example based on sleep position and sleep stages of a user. In some embodiments target pressures for the sleep surface are iteratively adjusted over multiple sleep sessions so to achieve improvements in sleep states and/or sleep quality for the user.

The present invention relates to a supporting module (100) for use in an adaptive sleep system and to a sleep system comprising such supporting modules, the resistance (resilience) of which can be adapted in a simple manner to the anatomy and/or posture of a user. The supporting module (100) for an adaptive sleep system comprises an uppermost supporting element (110), at least two drive shafts (140, 140′), at least two leaf springs (130, 130′) positioned parallel to one another, each leaf spring (130, 130′) including a first and a second end, each first end being connected to the first supporting element, and each second end being in contact with an adjacent drive shaft (140, 140′) via a coupling element (150), wherein the position of the second end of a leaf spring (130, 130′) with respect to the adjacent drive shaft (140, 140′) determines the deformation resistance of this leaf spring (130, 130′), and wherein the coupling element (150) has been configured to transmit the rotational motion of at least one drive shaft (140, 140′) to the leaf spring (130, 130′), in order to modify the position of the second end of the leaf spring (130, 130′) with respect to the adjacent drive shaft (140, 140′).

This invention is a device which creates adjustable acoustic and/or thermal zones in a bed to address sleep issues such as bed partner snoring and hot flashes. Adjustable acoustic bed zones can be created with a flexible movable partition which longitudinally spans a bed from an arch at the head of the bed to an arch at the foot of the bed. Adjustable thermal bed zones can be created with inflow and outflow flexible longitudinal air tubes which are inserted into a space between layers of bedding.