SE539075C2 - Adjustable cushion - Google Patents

Description

Technical Field The present invention relates to a set of spring sections according to the preamble of the independent claim.

In particular, the set of spring sections is intended to form a pad with adjustable hardness.

Technical position There are a large number of solutions for how a cushion should be designed to solve various problems. This invention aims to solve the following problems: • Increase comfort by distributing the weight of the load-bearing body over as large an area as possible even when the shape of the body is irregular.

Possibility to regulate the hardness of the bed suspension.

• Gaps and collisions between spring sections in beds with adjustable angle between different sections.

To solve the problem, the following should be increased: • The number of free-standing spring sections per unit area is increased, but the suspension depth and stability of the individual spring elements must be maintained or improved. • The spring in the spring element is prestressed by varying the distance between the surfaces that compress the spring. • The spring elements maintain their vertical direction of movement to avoid play or collisions between down modules when angled.

Problem Solving The present invention solves the problems of the prior art in that it has the features set forth in the appended claims.

The invention relates to a set of suspension elements which together with a frame constitute a cushion module. This construction is then the basis for additional functions in the form of adjustable suspension and improved suspension in the boundary zone between angled cushion modules.

The cushion module consists of a module body and a set of spring elements. The spring elements consist of a rod, spring, top, stop and / or an intermediate stop. The module body consisting of the module body's end, upper part and lower part which have a set of holes as well as adjustable fasteners and guide sleeves.

The hole sockets have the same pattern on both the upper and the lower part. The spring elements are placed in these paired hole sets.

The diameter of the rod is smaller than the hole of the frame. The spring, the top, the intermediate stop and the stop have a larger outer diameter than the hole of the frame, which locks the rod to a specific movement space vertically. The inner diameter of the spring is larger than the outer diameter of the rod.

The hole of the frame secures the rod laterally, the rod in turn constitutes a side statue for the spring, which allows higher and narrower spring elements, which in turn allows more spring elements per unit area and greater suspension depth.

The spring elements are placed in such a way that maximum density is obtained without the spring elements coming into contact with each other.

The lower part of the module body is raised and lowered as the attachment in the end of the module body is adjustable. It allows the cushion module's springs to be biased in a compressed position, which provides the opportunity to regulate the cushion's resilience hardness, a cushion with the possibility of adjustment between soft and firm! Height adjustment can be solved in several different ways. The adjustable fasteners can consist of electric motors that are adjusted in height by means of threads on the end of the module body. Alternatively, the lower part can be adjusted in height by means of wires which at one end are attached to the lower part and at the other part are controlled by an electric motor which is anchored in the bed frame. Depending on the embodiment, the lower part of the springs is loaded upwards or downwards. The electric motor biases the springs with the help of wires that attach to the lower part via pulleys.

Finally, the problem of the springs colliding or separating from each other along the line of refraction in between different sections with adjustable angle is solved. The solution is based on the spring elements maintaining their vertical position even when the cushion module is angled. This is done by the top and bottom part of the module body being articulated via articulated attachment to the ends of the module body, which allows angling of the top and bottom part with a maintained vertical position between the hole pairs which constitute directional support for the spring elements. When several cushion modules are assembled, at least one module headboard must be fixed vertically to the underlying bed frame. The other cushion modules that are attached to each other's modular ends can be angled in relation to the adjacent module while maintaining the vertical direction for all frame ends and holes. The module ends that are adjusted in height to achieve an angled cushion module can, for example, be raised and lowered by means of a lever controlled by an electric motor attached to the bed frame.

List of figures Brief description of figures Fig. A shows a set of spring elements (2) attached to the frame (3).

Fig. B shows spring elements (2) seen from the side, attached to the module body (3) with the springs (2.2) mounted above the upper part (3.1) of the body module. Fig. C shows spring elements (2) with the springs (2.2) mounted between the lower part (3.2) of the body module and the intermediate stop of the rod (2.1.2). Fig. D shows a simplified side view of a cushion module with adjustable hardness in the suspension, with the springs (2.2) mounted above the upper part (3.1) of the body module. Fig. E shows a simplified view from the side of a cushion module with adjustable hardness in the suspension, with the springs (2.2) mounted above the lower part (3.2) of the body module. Fig. F shows an angular cushion module (1) with the springs (2.2) mounted above the upper part of the body module (3.1). Fig. G shows an angular cushion module (1) with the springs (2.2) mounted between the lower part (3.2) of the body module and the intermediate stop (2.1). 2).

Fig. F2 shows an angular cushion module with electric motor (8) with lever (9).

Fig. G2 shows an angular cushion module with height adjustment function (4.1) Fig. H shows a bed frame (4) seen from the side equipped with lifting function (4.1) and three cushion modules (1). Fig. I shows the upper part (3.1) and lower part (3.2) of the module body showing the holes (3.3) that create pairs of holes (3.3.1).

Fig. J shows a set of holes (3.3) seen from above.

Fig. K shows a solution with electric motor (8) for biasing the springs (2.2) Fig. L shows a solution with electric motor (8) for biasing the springs (2.2) Image available on "Original document" Image available on "Original document" Detailed description of the invention Fig. A shows a simplified embodiment of a cushion module (1) consisting of a set of spring elements (2) attached to the module body (3). The spring elements (2) are placed to achieve the maximum number per unit area without the rods (2.1) being pressed against each other as they must be able to move independently of each other in the up and down direction. The optimal pattern is that the spring elements (2) are placed in rows, where each row is offset by half a rod (1) in diameter. The module body (3) consists of an upper part (3.1) and a lower part (3.2) which is provided with a number of holes (3.3). Fig. B shows spring elements (2) seen from the side, attached to the module body (3) where the rod (2.1) is placed in a hole (3.3). The spring (2.2) rests on the upper part of the body (3.1), which is supported by the rod (2.1). The left spring element (2) is unloaded by external force, the spring (2.1) acts on the rod (2.1) in the upward direction which is hindered by the lower stop of the rod (2.1.3). The right spring element (2) is actuated by an external force (5) from above so that the spring (2.2) is compressed to its maximum, which means that the spring element has assumed its lowest position. The position difference between the left and the right spring element (2) gives the cushion module's spring depth (2.3) Fig. C shows the spring element (2) seen from the side, attached to the module body (3) where the rod (2.1) is placed in the hole (3.3). The spring (2.2) rests on the lower part of the body (3.2), which is supported by the rod (2.1). The left spring element (2) is unloaded by external force, the spring (2.1) acts on the rod (2.1) in the upward direction which is hindered by the intermediate stop of the rod (2.1.2). The right spring element (2) is affected by an external force from above so that the spring (2.2) is compressed to its maximum, which means that the spring element has assumed its lowest position. The position difference between the left and the right spring element (2) gives the cushion module's spring depth (2.3) Fig. D shows a simplified view from the side of a cushion module with the springs (2.2) mounted above the upper part of the body module (3.1). The figure shows how the lower part of the body module (3.2) affects the spring (2.2). When the lower part (3.2) is in its highest position (3.2.1) the spring (2.2) is unloaded, see the left spring, when the lower part (3.2) is in its lowest position (3.2.2) the rod (2.1) is pulled down by its lower stop (2.1.3), the top of the rod (2.1.1) compresses the spring (2.2), see the right spring. Fig. E shows a simplified side view of a cushion module with the springs (2.2) mounted above the lower part (3.2) of the body module. The figure shows how the lower part of the body module (3.2) affects the spring (2.2). When the lower part (3.2) is in its lowest position (3.2.1) the spring (2.2) is unloaded, see the left spring, when the lower part (3.2) is in its lowest position (3.2.2) the spring (2.2) compresses between the lower part of the frame (3.2) and the intermediate stop of the rod (2.1.2), see the right spring. The support sleeve (3.2.3) fits between the rod (2.1) and the spring (2.2) and its purpose is to ensure support for the rod (2.1) when the lower part (3.2) of the frame assumes a position below the lower part of the rod (2.1). Fig. F shows a simplified view from the side of a cushion module with the springs (2.2) mounted above the upper part (3.1) of the body module where the ends (3.4) of the module body (3) are displaced in height. This is made possible by the articulated attachment (3.6) which links the upper part of the module body (3.1) in the upper side of the frame end (3.4) and by the articulated and / or height-adjustable attachment (3.7) which links the lower part (3.2) of the body to the end (3.4). lower area. One of the ends of the cushion module (3.4) is fixed either in the bed frame (4) or by a nearby cushion module (1.1). The diameter of the hole (3.3) of the frame allows the passage of a vertical rod (2.1) even when the lower and upper part of the frame are inclined. Fig. G shows a design similar to Fig. F, but with the difference that the springs (2.2) are mounted between the lower part (3.2) of the body module and the intermediate stop (2.1.2) of the rod. Fig. F2 shows a simplified view of an angular cushion module with electric motor (8) with lever (9) which affects the end of the cushion module (3.4) in height. Fig. G2 shows a simplified view of an angular cushion module with height adjustment function (4.1) which affects the end of the cushion module (3.4) in height. Fig. H shows a simplified view of a bed frame (4) from the side. The bed frame (4) is equipped with a lifting function (4.1) which can adjust the height and angle of the three different cushion modules (1). Each cushion module (1) consists of a set of spring elements (2). Fig. I shows a simplified view of the upper part (3.1) and lower part (3.2) of a modular frame, both of which have a set of holes (3.3) in the same pattern. Each hole (3.3) on the upper part (3.1) creates a pair of holes (3.3.1) with a hole (3.3) on the lower part (3.2) Fig. J shows a simplified view of a set of holes (3.3) seen from above.

Fig. K shows a simplified view of a solution with an electric motor (8) which adjusts the load on the springs (2.2) with wires (7) and pulleys (6) by pulling the lower part (3.2) downwards. Fig. L shows a simplified view of a solution with an electric motor (8) which adjusts the load on the springs (2.2) with wires (7) and pulleys (6) by pulling the lower part (3.2) upwards.

By Cushion module (1) is meant; cushion, bed, bed, part of bed or other construction with the intention of achieving that the pressure from the weight of a load-bearing body is distributed over as large an area as possible. The pad consists of spring elements (2) and module body (3) With the adjacent pad module menas, adjacent pad module or adjacent construction to the pad module.

By Spring element (2) is meant a unit consisting of; Rod (2.1), Spring (2.2), and the constituent components of these units, or any other structure which may constitute a resilient function.

MedStav (2. ~ \) means; rod, bar, stay cylinder or other fixed structure which does not change shape when subjected to forces MedTopp (2.1.2-3) means; top, top, reclining surface, sprinter, nut or other structure that constitutes the top of the rod (2.1). The top can run through the hole of the frame (3.3), or through the spring (2.2), which prevents the rod (2.1) from moving vertically unhindered.

MedStop (2.1.2-3) means; stop, sprinter, nut or other structure that cannot pass through the hole of the body (3.3), which prevents the rod (2.1) from moving freely vertically.

By Feather (2.2) is meant; spring, compression spring, coil or other resilient structure that is compressed by pressure.

By Suspension depth (2.3) is meant; suspension depth, stroke or other expression to describe the height differences between the maximum of the spring element (2) and the minimum height.

By module module (3) is meant; body, base, bottom or other structure that allows attachment of spring elements (2) and has sufficient strength to not be deformed by the forces to which it is subjected. The upper (3.1) and lower part (3.2) of the frame are perforated with holes (3.3) MedOvandel (3.1) means; upper part, upper part, upper side, surface which constitutes the upper part of the construction of the module body (3), or other construction which in some direction fixes the spring elements (2).

By Subpart (3.2) is meant; lower part, lower part, underside, surface which forms the lower part of the construction of the module body (3), or other construction which in some direction fixes the spring elements (2). That surface can occupy a higher height position than the lower parts of the module body.

By Lower part in position unloaded (3. 2.1) is meant the position occupied by the lower part of the module body when the springs (2.2) are not prestressed. Depending on how the springs are placed in the construction, this position is the upper or lower position.

By Lower part in position loaded (3.2.2) is meant the position occupied by the lower part of the module body when the springs (2.2) are prestressed / loaded due to the lower part (3.2) compressing the springs (2.2). Depending on how the springs are placed in the construction, this position is the upper or lower position.

By Steering sleeve (3.2.3) is meant; guide sleeve, hole, hollow cylinder or other structure whose purpose is to stabilize the lateral position of the rod (2.1).

MedHål (3.3) means; holes, punching, or other machining of the upper and lower part of the frame (3.1-2) in which the rod (2.1) can run freely through while the stop (2.1-3) and spring (2) of the rod are prevented from passing through. The hole (3.3) shall constitute a lateral fixation.

MedHålpar (3.3.1) means; holes, tubes or other structures which create which create a statute for a rod (2.1) By the end of the module frame (3.4) is meant; headboard in the module body, headboard, side, short side or other construction which constitutes the side of the module body (3) which either forms a side along the short side of the bed or a side which connects to a nearby module.

By Adjustable attachment (3.5) is meant; adjustable attachment, height and lowering bracket or other construction that also provides an attachment between the end (3.4) and the upper or lower part (3.1-2) with the possibility of height adjustment along the side of the end (3.4).

Joint mounting (3.6) means; articulated attachment, angular bracket or other construction that allows the module or upper part (3.1-2) of the module body to be attached and angled to the end of the body (3.4) By articulated and adjustable (3.7) means a bracket that is either articulated or adjustable or both.

By Bed frame (4) is meant; bed frame, frame, frame or other structure intended to form a cohesive basic structure for the cushion modules (1) By Height adjustment function (4.1) is meant; height adjustment function, lifting arm, lever, hydraulic system, electric lift or other construction that can adjust the height and angle of the cushion module (1) in relation to the bed frame (4). The height adjustment function can for example consist of an electric motor which is attached to the body (4) and generates a turn that controls a lever that lifts the end of the module body (3.4) MedKraft (5) is meant; force, weight, load, strain, pressure or other external influence resulting in the rods (2.1) being pushed downwards.

MedTrissa (6) means; pulley, wheel, sliding surface or other construction that can guide and angle, for example, a wire with the least possible friction.

MedVajer (7) means; wire, rope, string or other construction that can be loaded with a traction force.

By electric motor (8) is meant; electric motor, motor or other equipment that can be electrically controlled to produce a certain force in the form of, for example, rotation, pressure and traction.

MedHävarm (9) means; lever, rod or other device that can transmit power from, for example, an electric motor (8).

Claims (4)

Cushion module (1), characterized by a set of spring elements (2) mounted in a module body (3) which consists of an upper part (3.1) and a lower part (3.2) which have a certain mutual parallel distance, both parts have a set of holes ( 3.3) according to the same pattern. The upper (3.1) and lower part (3.2) of the frame create sets of holes (3.3.1) in which the spring elements (2) are placed vertically, each spring element consists of rod (2.1) and spring (2.2), the diameter of the rod (2.1) is smaller than the diameter of the body hole (3.3), the top (2.1.1) of the rod above the upper part (3.1) of the frame and the lower part of the rod (2.1) below the lower part (3.2) of the frame have a stop (2.1.3) and / or an intermediate stop (2.1. 2) with a larger diameter than the hole (3.3) of the frame, the movement of the rod (2.1) is radially limited by the hole of the frame (3.3). Each rod (2.1) forms a radial support for an enclosing vertically placed spring (2.2) whose upward movement is hindered either by the top of the rod (2.1.1) or by an intermediate stop (2.1.2) placed on the rod (2.1) between the upper part of the frame (3.1 ) and lower part (3.2), the bottom of the spring (2.2) rests either on the upper part of the frame (3.1) or on top of the lower part (3.2) of the frame. The distance between the upper part (3.1) of the module body and the lower part (3.2) can be adjusted in height when the lower part (3.2) is anchored to the end of the module body (3.4) via an adjustable attachment (3.5). The distance between the upper and lower part of the body (3.1-2) affects the compression of the spring (2.2) without load from above loading the spring element (2), either the spring (2.2) is compressed between the upper part (3.1) of the module body and the top of the spring element (2.1.1), or the spring is compressed between the lower part of the module (3.2) and the intermediate stop of the spring element (2.1.2). Cushion module according to Claim 1, characterized by hinged and adjustable fasteners ( 3.6-7) between the ends of the module body (3.4) and the upper and lower part of the module body (3.1-2). At least one of the headboards (3.4) in at least one cushion module (1) is fixed vertically to a bed frame (4), all cushion modules (1) are interconnected via its modular gables (3.4). Height adjustment function ( 4.1) regulates the height of some of the ends of the module frame (3.4) in relation to the bed frame (4), the vertical distance between the upper and lower part of the frame (3.1-2) is not affected by these being angled as the distance between the articulated fasteners (3.6-7 ) is not affected by the slope. The diameter of the hole (3.3) of the body allows the passage of a vertical rod (2.1) even when the lower and upper part of the body (3.1-2) is inclined, which allows the spring elements (2) to maintain their vertical position even when the cushion module (1) is angled.