System for adjusting pressure locally on the skin and subcutaneous tissue

Abstract

A system for adjusting pressure locally acting on the skin including a set of adjacent modules distributed so as to form a layer each module includes a cushion capable of changing shape and comprising a cavity, a valve, a tank, and a pressure sensor, wherein the cavity and the tank are in communication with each other by means of the valve, and the sensor is placed so as to sense pressure directly or indirectly acting on the cushion and a feedback loop arranged such as to increase or decrease the change in the shape of the cushion on the basis of the pressure detected by the sensor.

Claims

1. A system for locally adjusting a pressure on a skin of a user, the system comprising: a set of adjacent modules arranged to form a layer, each module of the set of adjacent modules including, a deformable cushion having a cavity and configured to deform along a longitudinal axis, a valve, a housing having a reservoir and a biasing structure, wherein the biasing structure is located in the reservoir, the cavity of the deformable cushion and the reservoir including a liquid fluid, the cavity and the reservoir communicating with the valve, the valve located between the cavity of the deformable cushion and the reservoir, the valve providing for a direct fluidic connection between the cavity of the deformable cushion and the reservoir for liquid fluid exchange, and a pressure sensor configured to detect a pressure acting directly or indirectly on the deformable cushion, and wherein the deformable cushion comprises a lip that allow sealing of an upper portion of the housing, and wherein the biasing structure is configured to provide a biasing force that pushes the liquid fluid toward the deformable cushion along the longitudinal axis in response to the deformable cushion pushing the liquid fluid against the biasing structure, and wherein a position of the valve is configured to be changed to control a flow rate of the liquid fluid between the cavity of the deformable cushion and the reservoir to increase or reduce a deformation of the deformable cushion according to the pressure detected by the pressure sensor.

2. The system as claimed in claim 1, wherein each module of the set of adjacent modules is not in fluidic connection with another module.

3. The system as claimed in claim 1, wherein at least two of the modules of the set of adjacent modules are in fluidic connection with each other.

4. The system as claimed in claim 1, wherein the biasing structure is a spring configured to exert a restoring force in a direction of the deformable cushion.

5. The system as claimed in claim 1, wherein the biasing structure is an elastic membrane configured to exert a restoring force in a direction of the deformable cushion.

6. The system as claimed in claim 1, wherein the liquid fluid comprises a magnetorheological fluid (MRF).

7. The system as claimed in claim 1, wherein the pressure sensor is arranged on an outer face of a wall of the deformable cushion, configured to directly measure an external pressure that acts on the deformable cushion.

8. The system as claimed in claim 1, wherein the pressure sensor is arranged in the cavity of the deformable cushion, configured to measure the pressure inside the cavity.

9. The system as claimed in claim 1, wherein the set of adjacent modules is dimensioned to cover a surface of at least one of a forefoot and a heel.

10. The system as claimed in claim 1, wherein the cavity of the deformable cushion, the valve, and the reservoir of each module form a closed fluidic system.

11. The system as claimed in claim 1, wherein liquid fluid is incompressible.

12. The system as claimed in claim 11, wherein the valve is configured to take an open and a closed position, and in the closed position, the deformable cushion is rigid, while in the open position, the deformable cushion is able to deform by permitting a liquid fluid flow between the cavity of the deformable cushion and the reservoir.

Description

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

(1) FIG. 1 depicts a system according to the prior art;

(2) FIGS. 2A and 2B show different views of the system that can change the stiffness/pliability in different zones below the surface;

(3) FIG. 3 shows an exemplary view of the individual module with a cushion, a reservoir, and a control valve;

(4) FIG. 4 shows a side view of the system with a plurality of variable stiffness modules;

(5) FIG. 5 shows a perspective view of the system with a plurality of variable stiffness modules;

(6) FIGS. 6A to 6C show exemplary views of different states of the variable stiffness module;

(7) FIGS. 7A to 7C show different views of the components that can form the variable stiffness module with a mechanical spring;

(8) FIGS. 8A to 8C show exemplary views of different states of the variable stiffness module that uses a circular elastic membrane; and

(9) FIG. 9A to 9C show different views of the components that can form the variable stiffness module with the elastic membrane.

DESCRIPTION OF THE INVENTION

(10) The disadvantages of the prior art are greatly reduced, if not totally eliminated, by virtue of the present invention which relates to a system for adjusting the pressure acting locally on the skin and subcutaneous tissue. The system comprises a set of adjacent modules distributed in such a way as to form a layer; each module comprises the following elements arranged along a same direction: a deformable cushion comprising a cavity, a valve, a reservoir, and a pressure sensor.

(11) The cavity and the reservoir communicate by way of the valve, and the sensor is arranged in such a way as to detect a pressure acting directly or indirectly on the cushion. To this end, it can be arranged on the wall of the cushion (direct measurement) or inside the cavity. In the latter case, the pressure of the liquid is measured (indirect measurement). The system additionally comprises a feedback loop arranged in such a way as to increase or reduce the deformation of the cushion according to the pressure detected by the sensor.

(12) Advantageously, the system according to the invention comprises several miniaturized and adjacent modules which cover the surface of the forefoot and/or of the heel. They are arranged with a sufficient density to correctly detect the different zones of excessive pressure. The system is preferably capable of modifying the stiffness of each of the modules (thus permitting their deformation) and of thereby permitting a redistribution.

(13) The system according to the invention can also include guide means which mechanically constrain the displacement of an element arranged in the reservoir (plunger or elastic membrane). In addition, any shearing force that may come into play in the contact between foot and module is taken up by the cushion without adversely affecting the functioning of the actual module.

(14) The modules can be fluidically independent or can communicate with each other. Each module defines a certain surface area. The set of modules makes it possible to change the stiffness/pliability in different zones below the surface of the system, for example a foot (FIGS. 2A and 2B). The system according to the invention in particular solves the problems of localized excessive pressure on the plantar surface of the feet. The system is capable of measuring and detecting the zones that have pressure peaks and of adapting its shape in order to redistribute the latter homogeneously. It is thus possible to control the height of each of the modules in order to modify the shape of the sole, dynamically when the patient moves. The change in the properties of each module of the sole (and therefore of the sole itself) is effected in relation to the information obtained by the pressure measurements of each of the sensors present on the different modules.

(15) A module is composed of three main parts (FIG. 3), namely (i) a deformable cushion having a cavity intended to receive a fluid, (ii) a reservoir, and (iii) a control valve arranged between the cushion and the reservoir.

(16) According to one embodiment of the invention, the cushion is arranged in the upper part of the module. It is made of a flexible and deformable material. The geometry of the cushion can be of a bellows shape. Other geometries facilitating the deformation in a preferential direction (here vertical) are also possible. The cushion is filled with an incompressible fluid (water, oil, magneto-rheological fluid, etc.). In the variant in FIG. 3, a pressure sensor is arranged in the upper part and on the inner face of the wall of the cushion. This measurement permits determination of the contact pressure between the patient's foot and the deformable cushion. Other pressure sensors can also be used inside or outside the cushion. Any other arrangement of the measurement system permitting determination of the contact pressure between the foot and the actual module may be envisioned as a possible solution.

(17) The valve controls the flow rate of the fluid moving between the cavity of the cushion and the reservoir. Preferably, the valve is designed to occupy the same surface area as that of the cushion. This vertical arrangement of the main parts of the module makes it possible to maximize the density of modules for a given surface area. More precisely, any sort of valve having the ability to satisfy the demands of dimension, miniaturization, energy consumption, maximum attainable pressure and maximum flow rate for the application and configuration (below the deformable cushion) may be considered as possible solutions.

(18) The fluid entering the reservoir comes from the cavity of the cushion and, if the modules are fluidically connected, of the other modules.

(19) The functioning of a module can be defined by three states: Valve closed: The cushion maintains its initial position and remains rigid, the fluid being incompressible and having no possibility of entering and/or leaving the cavity. In this case, if an external pressure (e.g. the patient's foot) is exerted on the module, the cushion does not deform. The module thus acts as a rigid sole element. Valve open: The cushion is able to deform since the fluid contained in the cavity can move into the reservoir. Control of the flow rate of the fluid: Acting in the area of the valve. In this case, the module will have a variable stiffness.

(20) For a normal liquid, the flow rate is controlled by increasing or reducing the opening of the valve.

(21) Alternatively, a magneto-rheological fluid (MRF) and an MRF valve may be used.

(22) An MRF is composed of a non-magnetic liquid (water or oil) in which magnetic particles (generally iron powder) are dispersed. The main property of this liquid is its ability to change viscosity when subjected to a magnetic field.

(23) An MRF valve is composed of a magnetic circuit and of an element creating a magnetic field (for example a coil, magnet, etc.). The interaction of the magnetic field and of the MRF produces a change of viscosity of the latter and therefore modifies its passage through the valve. If the strength of the magnetic field is sufficiently high, the MRF becomes viscous, to the point that its flow rate through the valve is close to or equal to zero.

(24) As has been indicated above, the modules can be arranged and connected in different ways.

(25) I. Communicating Modules

(26) In this configuration, the liquid is able to pass from one module/cushion to another through a communication channel. The valve corresponding to each module controls the passage of the fluid from the deformable cushion to the common channel. FIGS. 4 and 5 show a schematic view of the common channel in one embodiment.

(27) This solution ensures greater flexibility, a high level of integration, and simplicity in terms of the design of the overall system.

(28) II. Independent Modules

(29) In this variant, the module constitutes a discrete system. The valve regulates the passage of the liquid between the cushion and the reservoir, thereby controlling the height and the stiffness of the module, as described above.

(30) For correct functioning of the module, it is necessary that the cushion is able to return to its initial (undeformed) configuration/height once the pressure of the foot is withdrawn from said cushion: it is therefore necessary to return the MRF from the reservoir into the cushion. To achieve this function, two different solutions are described below.

(31) 1. System with a Plunger Driven by a Spring

(32) When the liquid flows from the cushion into the reservoir on account of the pressure of the foot, the plunger is pushed downward and the spring compresses. Once the pressure of the foot is withdrawn, the spring causes the liquid to rise into the cushion (FIGS. 6A-6C and 7A-7C).

(33) Springs of different stiffness can be used to obtain variable effects.

(34) 2. System with a Deformable Elastic Membrane Made of Latex

(35) In this variant, a circular elastic membrane is positioned just below the valve. Once the liquid is pushed downward on account of the deformation of the cushion, the latex membrane (or any other elastic and leaktight element) deforms in order to receive the liquid. It is able to deform until it covers the entire volume of the reservoir. Once the pressure of the foot on the module is withdrawn, the membrane returns to its initial configuration, which causes the liquid to rise toward the cushion (FIGS. 8A-8C and 9A-9C).

(36) It is possible to use membranes of different thickness in order to regulate the restoring force that causes the liquid to rise into the cavity of the cushion.

(37) The invention is not limited to the examples set out in this document. It is possible to use any kind of module that ensures regulation of the pressure acting locally on the skin and subcutaneous tissue.

(38) Moreover, the invention is not limited to a specific geometry, arrangement or size of the modules.