HUMAN HEAD SUPPORT DEVICE

The head support device with superimposed pneumatic chambers addresses instability and discomfort by offering adjustable height and stability, preventing pressure sores and ensuring comfort, with cost-effective and versatile design.

FR3170256A1Pending Publication Date: 2026-06-26MICHELIN & CO (CIE GEN DES ESTAB MICHELIN)

Patent Information

Authority / Receiving Office
FR · FR
Patent Type
Applications
Current Assignee / Owner
MICHELIN & CO (CIE GEN DES ESTAB MICHELIN)
Filing Date
2024-12-19
Publication Date
2026-06-26

AI Technical Summary

Technical Problem

Existing head support devices fail to provide adjustable height and stability, leading to instability and discomfort, especially for patients requiring specific head positioning during surgeries or rest, and do not effectively prevent pressure sores.

Method used

A head support device comprising at least two superimposed pneumatic chambers made of thermoplastic polymer sheets, connected immovably and maintained under pressure, allowing adjustable height and enhanced stability, with optional reinforcement and ventilation features.

Benefits of technology

The device ensures stable and adjustable head positioning, reduces the risk of pressure sores, and provides comfort by conforming to individual head shapes, while being cost-effective and easy to store.

✦ Generated by Eureka AI based on patent content.

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Abstract

The invention relates to a device for supporting the head of a human body in a supine position on a horizontal plane. According to the invention, the device consists of at least two pneumatic chambers superimposed in the vertical direction, at least two pneumatic chambers being permanently linked, and at least the pneumatic chamber resting on the horizontal plane being kept under pressure. Figure for the abstract: [Fig 1]
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Description

Title of the invention: HUMAN HEAD SUPPORT DEVICE

[0001] The present invention relates to a device for supporting the head of a human body in a fixed position. Although not limited to this type of application, the invention will be described more particularly with reference to the case of patients in a hospital setting when they are to undergo surgery, whose head must be stable and in a specific position.

[0002] Other types of applications include, for example, pillows or headrests for hospital or domestic use to provide support and comfort in a specific position.

[0003] In many situations, hospitalized patients, whether in a room or in the operating room, must remain lying still on their backs or in a supine position. Regardless of the quality of the mattress, it appears necessary to keep the head elevated to avoid disturbing the cervical vertebrae and to maintain spinal alignment. During surgery, it may also be necessary to reposition the head during the procedure to access specific areas.

[0004] A technique currently used in hospitals involves the use of foam or gel wedges. This type of wedge does not allow for adjusting the head support height and therefore cannot adapt to the different morphologies of patients or to situations requiring specific operations.

[0005] Document EP0736278A1 describes an inflatable cushion to improve the comfort of a patient who must remain seated. This cushion consists of multiple cells containing a fluid and controlling the flow of fluid from one cell to another. Such a device offers no guarantee of stability and does not allow for adjustment of the head position.

[0006] US patent 20170065473A1 describes an inflatable device for supporting an individual, allowing for simplified application. When used for the head, this type of device does not provide the desired stability.

[0007] Document WO98 / 55013 describes a device for supporting a body during radiographs comprising inflatable parts to allow positioning of the body.

[0008] The inventors have thus set themselves the task of proposing a support device for the head of a human body, allowing the choice of a support height and ensuring improved stability compared to known devices.

[0009] This goal has been achieved according to the invention by a device for supporting the head of a human body in a supine position on a horizontal plane, said device being made up of at least two pneumatic chambers superimposed in the vertical direction, at least two pneumatic chambers being linked in a non-removable manner and at least the pneumatic chamber resting on the horizontal plane being kept under pressure.

[0010] The head support device of a human body thus described according to the invention makes it possible to support the head of the human body in a desired position by reducing the risk of unwanted displacements.

[0011] The inventors were first able to demonstrate that the superposition of inflatable chambers makes it possible to adjust the height of head support.

[0012] The inventors have also demonstrated that pressurizing at least one pneumatic chamber resting on the horizontal plane and ensuring the fixed connection between two chambers provides entirely satisfactory stability to the device. In particular, the inventors believe that, for a given height, the vertical superposition of at least two chambers provides greater stability than a device consisting of a single pneumatic chamber. Furthermore, they believe that to reduce the height of the support device, the presence of at least two vertically superimposed pneumatic chambers, which allows only one pneumatic chamber to be inflated, maintains superior stability compared to a device consisting of a single pneumatic chamber, for which the inflation pressure of that single chamber would have to be reduced.

[0013] According to an advantageous embodiment of the invention, said at least two pneumatic chambers being made up of at least two sheets of thermoplastic polymer, one of said at least two sheets of thermoplastic polymer is common to two pneumatic chambers.

[0014] The common part of two pneumatic chambers, which constitutes the common thermoplastic polymer sheet, gives the immovable character of the bond between said two pneumatic chambers.

[0015] Preferably according to the invention, at least one of said at least two pneumatic chambers is made up of at least two sheets of thermoplastic polymer connected at their periphery and of at least one substantially vertical wall made up of a sheet of thermoplastic polymer welded along its length to each of the internal surfaces of two of said at least two sheets of thermoplastic polymer.

[0016] Said at least one substantially vertical wall is advantageously dimensioned to create two volumes which communicate with each other to allow the inflation of the pneumatic chambers from a single orifice.

[0017] Said at least one substantially vertical wall, according to its dimensions, defines the distance between said two sheets of thermoplastic polymer and defines the external shape of the pneumatic chamber.

[0018] The pneumatic chamber advantageously comprises several substantially vertical walls, each consisting of a thermoplastic polymer sheet welded along its length to each of the internal surfaces of said two thermoplastic polymer sheets. Their distribution within the pneumatic chamber allows for optimal definition of the external shape of the pneumatic chamber.

[0019] According to an advantageous embodiment of the invention, the pneumatic chamber on which the head rests directly is maintained at a pressure under load of less than 20 millimeters of mercury (mmHg).

[0020] For the purposes of the invention, a pressure under load corresponds to the pressure measured when the head of the human body is in contact with the support device.

[0021] The inventors have further demonstrated that the pneumatic chamber which directly supports the head, at such pressure, provides comfort and in the event of prolonged pressure can prevent or at least limit the appearance of bedsores.

[0022] Pressure sores or necrosis can occur when pressure is exerted by the patient's weight between bony prominences and pressure points on the skin and flesh. These skin lesions result from prolonged pressure on certain parts of the body, leading to tissue ischemia and significant skin damage.

[0023] The inventors have indeed shown that the superimposed pneumatic chambers which are thus inflated according to the invention make it possible to maintain the head in the chosen position in a stable manner, providing comfort to the individual and limiting the risk of pressure sores.

[0024] According to one embodiment of the invention, a pneumatic chamber of the head support device for a human body is made of at least two sheets of thermoplastic polymer preferably having a tensile modulus at 10% elongation of less than 20 MPa, said at least two sheets of thermoplastic polymer being heat-welded edge to edge at their periphery. The pneumatic chamber of the device then has the shape of a cushion.

[0025] According to another embodiment, a pneumatic chamber of the head support device for a human body is made of at least three sheets of thermoplastic polymer, two of the thermoplastic polymer sheets being connected at their periphery by a third thermoplastic polymer sheet forming a vertical wall, said third thermoplastic polymer sheet being heat-sealed to the periphery of the first two thermoplastic polymer sheets. The three thermoplastic polymer sheets thus form a pneumatic chamber in the shape of a mattress. The three sheets of thermoplastic polymer preferably have a tensile modulus at 10% elongation of less than 20 MPa.

[0026] Measurements of moduli of elasticity under tension at 10% elongation are carried out according to DIN 53504.

[0027] The heat sealing of thermoplastic polymer sheets can in particular be carried out by ultrasound, conduction or high frequency.

[0028] Preferably, the thermoplastic polymer sheet(s) have a tensile modulus of elasticity at 10% elongation of less than 10 MPa.

[0029] Preferably, the thermoplastic polymer sheet(s) have a thickness of less than 1 mm and preferably less than 0.5 mm.

[0030] Such a material allows, in a known manner, the simple production of an element having a sealed pneumatic chamber that can be pressurized. A particularly suitable material is a thermoplastic polyurethane. It is possible to perform heat sealing by locally heating the sheet to its melting temperature. The rigidity properties of the sheet will help to reduce the risk of pressure sores when it is in contact with the skin. Heat sealing can be performed by ultrasound, conduction, or high frequency.

[0031] The choice of this thin and deformable material also allows it to conform to the head of the supported human body and thus optimize the contact surface between the support device and the head of the human body.

[0032] Furthermore, manufacturing the head support device for a human body from a heat-sealable material allows for a relatively precise shape. The shape of the support device can be defined by heat sealing.

[0033] When said at least two pneumatic chambers of the support device are made of at least two sheets of thermoplastic polymer, the thermoplastic polymer sheet(s) that do not come into contact with the skin of the human body are advantageously reinforced. This reinforcement may be based on fibers or fabrics and results in a thermoplastic polymer sheet that is more rigid than one having a tensile modulus of elasticity at 10% elongation of less than 20 MPa.

[0034] According to one embodiment of the invention, the head support device of a human body consists of at least three pneumatic chambers.

[0035] According to this embodiment of the invention, in the case of three pneumatic chambers, according to a first embodiment, the third pneumatic chamber is advantageously fixed to one of the other two pneumatic chambers. When said third pneumatic chamber is consisting of at least two sheets of thermoplastic polymer, it advantageously shares one with another pneumatic chamber.

[0036] According to this same variant of the invention, according to a second embodiment, the third pneumatic chamber can also be linked to another pneumatic chamber in a detachable manner by any separable linking means known to a person skilled in the art.

[0037] Separable connecting means are, for example, Velcro® type devices, each part of which is fixed to the surface of a pneumatic chamber by welding, sewing or any other suitable means.

[0038] Separable connecting means may also be any other type of fastening system which is advantageously simple to use, such as, for example, detachable zipper type fasteners or any type of quick-release buckle system.

[0039] According to a preferred embodiment of the invention, each of the pneumatic chambers has an inflation orifice.

[0040] Such inflation ports are, for example, connected to a tube and possibly to a valve. These inflation ports, present on each of the pneumatic chambers, ensure that the required pressure is maintained for each of the pneumatic chambers under the weight of the human head pressing against them, and allow for the possible control of the different pressures during the use of the device.

[0041] The inflation ports are advantageously positioned to be accessible during use and to prevent them from coming into contact with the human body. They are advantageously associated with tubes that allow the connection to the inflation device to be relocated and may be joined together to facilitate the pressurization of the pneumatic chambers.

[0042] The inflation ports are advantageously further associated with flap valves or tubes associated with "clamp" type clamps to ensure the best possible sealing.

[0043] An advantageous embodiment of the invention provides that at least a part of the surface of said device coming into contact with the head of a human body is covered with a 3D spacer fabric known as "3D spacer".

[0044] For the purposes of this invention, "3D spacer fabrics" are three-dimensional fabrics of the type "XD Spacer Fabrics" marketed by Baltex or "3D MESH SPACER FABRIC" marketed by Muller, which are already used in medical applications. These three-dimensional fabrics have the advantage of providing ventilation to the surface of the human skin in contact with the support module. Such fabrics are described, for example, in US patents 2018187348, EP 1347087, EP 2408957, and WO 2012098130.

[0045] Such "3D spacer" fabrics can be woven or knitted, consisting of two walls connected to each other by one or more filaments. These filaments can be of various materials: polyester, polyamide, polypropylene, or cotton. These filaments can be used in their raw state but also coated or coated to modify the feel or limit the growth of viruses or bacteria. These filaments have a certain resilience conferred by their diameter greater than 30 microns, preferably greater than 100 microns, and with a density and pattern adapted to withstand compressive forces; they thus give the "3D spacer" fabric a buckling strength, that is to say, resistance to compression or resistance to buckling of these filaments.

[0046] Advantageously the "3D spacer" fabric has a buckling stress greater than the inflation pressure of the pneumatic chamber.

[0047] In the context of the invention, the buckling stress of the fabric is the stress perpendicular to the median plane of the fabric that causes the filaments connecting the two surfaces to buckle. Beyond this stress, the two fabric surfaces come very close together and can no longer perform their ventilation function.

[0048] The average plane of the fabric corresponds to the surface of the fabric when it is laid flat.

[0049] The buckling stress is measured according to ISO 3386-1.

[0050] Advantageously, the buckling stress of the "3D spacer" fabric is less than 0.2 bar.

[0051] Such buckling constraints make it possible to combine ventilation of the skin of the human body and supportive comfort.

[0052] According to a preferred embodiment of the invention, the thickness of the "3D spacer" fabric is less than 10 mm.

[0053] Preferably according to the invention, the air permeability of the "spacer 3D" fabric is greater than 1000 l / dm2xmin under a pressure of 1 mbar.

[0054] The permeability of the tissue is measured according to ISO 9237.

[0055] The presence of a "3D spacer" fabric, advantageously exhibiting characteristics such as those described above, in contact with the skin of the supported body allows for the evacuation of moisture and heat and thus helps to preserve the skin which comes into contact with the support device.

[0056] According to one embodiment of the invention, the "3D spacer" fabric is provided to be removable and separable from the first element so that it can be properly cleaned and / or changed regularly.

[0057] It is still possible to provide a cover made with the "3D spacer" fabric enveloping the entire head support device of the human body; these covers being designed to be removable so that they can be properly cleaned and / or changed regularly.

[0058] Advantageously according to the invention, the inflation of the pneumatic chambers of the head support device of a human body is carried out with an inert and / or purified gas to avoid any additional risk of infection in the event of an accident on one of the pneumatic chambers leading to a leak, particularly when used in a hospital setting.

[0059] The invention as described above has several other advantages, particularly those related to the inflatable nature of the components of the head support device for a human body. Indeed, the use of inflatable components allows their volume to be reduced when not in use or before use, thus facilitating their storage.

[0060] Another advantage of the human head support device as presented relates to manufacturing costs, particularly due to the materials chosen. Indeed, the low costs for producing the support device according to the invention also allow for the availability of devices in different sizes or shapes for better adaptation to the size or build of the human body.

[0061] Combined with the gain in volume and the low cost of the support device, it becomes possible to store a large number and variety of these elements and thus to have at any time the model best suited to the situation, in particular in terms of variety of shapes.

[0062] Other details and advantageous features of the invention will become apparent from the description of the exemplary embodiments of the invention with reference to Figures 1 to 4, which represent: - [Fig. 1], a schematic representation of a first embodiment of a support device according to the invention, - [Fig.2], a schematic representation, viewed from above, of the first embodiment of a support device according to the invention, - [Fig. 3], a schematic representation of a second embodiment of a support device according to the invention, - [Fig.4], a schematic representation, top view, of the second embodiment of a support device according to the invention.

[0063] The figures are not shown to scale to simplify understanding.

[0064] In [Fig. 1], the head support device of a human body 1 comprises two superimposed pneumatic chambers 2, 3. Pneumatic chamber 2 consists of two sheets of thermoplastic polyurethane 4, 5 welded at their periphery along a line 6. Internal walls 7, formed of polyurethane sheets thermoplastic, are welded along their entire length to each of the faces of the two thermoplastic polyurethane sheets 4, 5, internal to the pneumatic chamber 2.

[0065] The pneumatic chamber 3 is made of two sheets of thermoplastic polyurethane 5, 8 welded to the periphery of the thermoplastic polyurethane sheet 8 which is lower than that of the thermoplastic polyurethane sheet 5. Internal walls 9, formed of sheets of thermoplastic polyurethane, are welded along their entire length to each of the faces of the two thermoplastic polyurethane sheets 5, 8, internal to the pneumatic chamber 2.

[0066] Thermoplastic polyurethane sheets are marketed under the name TUFTANE® TFL-1E and have a secant elongation modulus of 9.8 MPa at 10% elongation.

[0067] Figure 2 illustrates the support device for a human body 1 seen from above. In Figure 2, the thermoplastic polyurethane sheet 8 is shown, which is superimposed on the thermoplastic polyurethane sheet 5.

[0068] During use, the pneumatic chamber 2 is maintained at a pressure under load to ensure a height hl for the head support device of a human body 1, the pneumatic chamber 3 remaining deflated. When the pneumatic chamber 3 is also maintained at a pressure under load, the head support device of a human body 1 has a height h2, the head of the human body resting on the pneumatic chamber 2.

[0069] The head support device of a human body 1 can thus, for example, be adapted to different types of human bodies that may have different body sizes.

[0070] The pressurization of each of the pneumatic chambers 2 and 3 is achieved through valves, not shown in the figures, fitted to each of the pneumatic chambers 2 and 3. Each valve can be located at the end of a tube connected to one of the pneumatic chambers so that the valve is easily accessible to allow inflation to the desired pressure under load. These valves, or the tubes that allow them to be located there, are designed so as not to come into contact with the head.

[0071] Figure 3 illustrates a schematic representation of a second example of a head support device for a human body 21. The head support device for a human body 21 comprises two superimposed pneumatic chambers 22, 23. The pneumatic chamber 22 consists of two sheets of thermoplastic polyurethane 24, 25 welded at their periphery by means of a third sheet of thermoplastic polyurethane 26 forming a vertical wall and giving the pneumatic chamber 22 the appearance of a mattress. Internal walls 27, formed of sheets of thermoplastic polyurethane, are welded along their entire length to each of the faces of the two thermoplastic polyurethane sheets 24, 25, internal to the pneumatic chamber 22.

[0072] The pneumatic chamber 23 is made of two thermoplastic polyurethane sheets 25, 28 welded to the periphery of the lower thermoplastic polyurethane sheet 28, via a third thermoplastic polyurethane sheet 29 forming a vertical wall and giving the pneumatic chamber 23 the appearance of a mattress. Internal walls 30, formed of thermoplastic polyurethane sheets, are welded along their entire length to each face of the two thermoplastic polyurethane sheets 25, 28, internal to the pneumatic chamber 23.

[0073] As in the case of device 1, the thermoplastic polyurethane sheets are marketed under the name TUFTANE® TFL-1E and have a secant elongation modulus of 9.8 MPa at 10% elongation.

[0074] Figure 4 illustrates the support device for a human body 21 seen from above. Figure 4 shows the thermoplastic polyurethane sheet 28 which is superimposed on the thermoplastic polyurethane sheet 25.

[0075] During use, the pneumatic chamber 22 is maintained at a pressure under load to ensure a height h21 for the head support device of a human body 21, the pneumatic chamber 23 remaining deflated. When the pneumatic chamber 23 is also maintained at a pressure under load, the head support device of a human body 21 has a height h22, with the head of the human body resting on the pneumatic chamber 23.

[0076] As in the previous case when using the support device 21, it is thus possible to adapt the height of the support device to the head of a human body 21.

[0077] Tests were carried out with a support device as shown in [Fig.1] and [Fig.2].

[0078] Before its installation, the support device is partially filled with inflation gas so as to separate the walls of the pneumatic chambers.

[0079] The support device is put in place and the two pneumatic chambers 2 and 3 are brought and maintained at the desired pressures under load.

[0080] The tests carried out showed that the support device according to the invention allows greater stability than that which would be provided by an air cushion consisting of a single air chamber allowing the same height to be ensured.

[0081] The pressure of the pneumatic chamber 3 on which the head rests can be further defined for optimum support, thereby reducing the risk of pressure ulcers by providing pneumatic support at the desired height and in a manner stable. The pressure under load of the pneumatic chamber 3 is then advantageously less than 20 mm of mercury (mm Hg).

[0082] The embodiments presented should not be interpreted as an exhaustive list. The shapes of the devices may vary, their embodiment may be different, and the number of pneumatic chambers in a device may be greater.

Claims

Demands

1. A head support device for a human body in a supine position on a horizontal plane, characterized in that said device consists of at least two pneumatic chambers superimposed in the vertical direction, in that at least two pneumatic chambers are linked in a non-removable manner and in that at least the pneumatic chamber resting on the horizontal plane is kept under pressure.

2. A head support device for a human body, according to claim 1, said at least two chambers being made up of at least two sheets of thermoplastic polymer characterized in that one of said at least two sheets of thermoplastic polymer is common to two pneumatic chambers.

3. A head support device for a human body, according to claim 1 or 2, characterized in that at least one of said at least two pneumatic chambers is made up of at least two sheets of thermoplastic polymer connected at their periphery and at least one substantially vertical wall made up of a sheet of thermoplastic polymer welded along its length to each of the internal surfaces of two of said at least two sheets of thermoplastic polymer.

4. A human body head support device according to any one of claims 1 to 3, characterized in that at least one pneumatic chamber of the human body head support device is made up of at least two thermoplastic polymer sheets heat-welded edge to edge at their periphery.

5. A human body head support device according to any one of claims 1 to 3, characterized in that at least one pneumatic chamber of the human body head support device is made up of at least three sheets of thermoplastic polymer, in that two sheets of thermoplastic polymer are connected at their periphery by a third sheet of thermoplastic polymer forming a vertical wall, and in that said third sheet of thermoplastic polymer is heat-welded at the periphery of the first two sheets of thermoplastic polymer.

6.

7.

8.

9. A head support device for a human body, according to any one of claims 1 to 5, characterized in that each of the pneumatic chambers has an inflation orifice. A head support device for a human body, according to any one of claims 1 to 6, characterized in that the device comprises at least one detachable pneumatic chamber. Human head support device according to claim 7, characterized in that said at least one detachable pneumatic chamber is associated with at least one other pneumatic chamber by means of connection. A head support device for a human body according to any one of claims 1 to 8, characterized in that at least a part of the surface of said device coming into contact with the head of a human body is covered with a "3D spacer" fabric.