Pressure sensor laminated onto a textile sheet, a method for manufacturing thereof, and a pressure distribution sensing product

The invention claimed is: 1. A pressure sensor laminated onto a textile sheet to form a pressure sensing textile sheet, the pressure sensor comprising: at least two adjacent electrically conductive leads disposed in a pattern on a face of a first elastomeric carrier; and an electrically resistive layer formed of a resistive composite material for shunting the at least two adjacent electrically conductive leads, said electrically resistive layer disposed on a face of a second elastomeric carrier; wherein the first elastomeric carrier and the second elastomeric carrier are stacked across a spacer such that the at least two adjacent electrically conductive leads face the electrically resistive layer across a gap defined by the spacer to form a pocket structure defining a gas confining structure that is filled with a gas that at least partly counters a force exerted on the pressure sensor, wherein the first carrier including the at least two adjacent electrically conductive leads and the second carrier including the electrically resistive layer are stretchable so as to, upon receiving the force exerted in a direction across the gap, reduce the gap between the electrically resistive layer and the at least two adjacent electrically conductive leads to shunt the at least two adjacent electrically conductive leads with the resistive composite material over a contact area in dependence on the force to result in a pressure dependent electrical resistance between the conductive leads, and wherein the pocket structure is provided with a relief structure of micro bumps and an opening to reduce the counter force of the gas, said opening being dimensioned to impede the gas from exiting the pocket. 2. The pressure sensor according to claim 1 , wherein the opening is formed in the spacer. 3. The pressure sensor according to claim 1 , wherein the pocket structure has a height, between the carriers, in a range between 0.5 and 500 micrometer and a width in a range between 0.5 and 2 cm. 4. The pressure sensor according to claim 1 , wherein the first carrier, the second carrier, and the spacer are formed of a composition comprising an elastomeric material having an elastic modulus below about 100 MPa. 5. The pressure sensor according to claim 1 , wherein the electrically resistive composite material comprises an interconnected network of conductive micro-particles in an elastomeric polymer matrix. 6. The pressure sensor according to claim 1 , wherein the pattern is arranged to, upon closing of the gap, form a gradually, and in a radial direction, increasing contact area between the electrically resistive layer and the at least two adjacent electrically conductive leads. 7. The pressure sensor according claim 1 , wherein the pocket comprises a plurality of connected compartments to redistribute the gas upon application of the force. 8. The pressure sensor according to claim 1 , wherein the electrically resistive layer exhibits a sheet resistance in a range of 1 kiloOhms/cm 2 to 500 kiloOhms/cm 2 . 9. The pressure sensor according to claim 1 comprising: a plurality of spatially separated ones of the at least two adjacent electrically conductive leads disposed in a pattern on the face of the first elastomeric carrier; and a plurality of spatially separated corresponding ones of the electrically resistive layers on the face of the second elastomeric carrier to form a plurality of pocket structures, each defining a gas confining structure that is filled with a gas. 10. The pressure sensor according to claim 9 wherein at least a first part of the plurality of pockets is dimensioned and/or shaped in accordance with a first sensitivity range, and wherein a second part of the plurality of pressure sensors is dimensioned and/or shaped in accordance with a second sensitivity range, different from the first, so as to extend an overall sensitivity range of the pressure sensor. 11. A pressure distribution sensing product comprising a plurality of pressure sensors, wherein the plurality of pressure sensors are arranged in a configuration for detecting pressure over an area according to placement of the plurality of pressure sensors, wherein each of the plurality of pressures sensors is: a pressure sensor laminated onto a textile sheet to form a pressure sensing textile sheet, the pressure sensor comprising: at least two adjacent electrically conductive leads disposed in a pattern on a face of a first elastomeric carrier; and an electrically resistive layer formed of a resistive composite material for shunting the at least two adjacent electrically conductive leads, said electrically resistive layer disposed on a face of a second elastomeric carrier; wherein the first elastomeric carrier and the second elastomeric carrier are stacked across a spacer such that the at least two adjacent electrically conductive leads face the electrically resistive layer across a gap defined by the spacer to form a pocket structure defining a gas confining structure that is filled with a gas that at least partly counters a force exerted on the pressure sensor, wherein the first carrier including the at least two adjacent electrically conductive leads and the second carrier including the electrically resistive layer are stretchable so as to, upon receiving the force exerted in a direction across the gap, reduce the gap between the electrically resistive layer and the at least two adjacent electrically conductive leads to shunt the at least two adjacent electrically conductive leads with the resistive composite material over a contact area in dependence on the force to result in a pressure dependent electrical resistance between the conductive leads, and wherein the pocket structure is provided with a relief structure of micro bumps and an opening to reduce the counter force of the gas, said opening being dimensioned to impede the gas from exiting the pocket. 12. A method for manufacturing a pressure sensor on a pressure sensing textile sheet, the method comprising: providing a first elastomeric carrier; providing a second elastomeric carrier; laminating a fabric sheet to the first carrier and/or the second carrier; and providing at least two adjacent electrically conductive leads in a pattern on a face of the first carrier; depositing an electrically resistive composite material on a face of the second carrier to form an electrically resistive layer for shunting the at least two adjacent electrically conductive leads; providing a spacer; providing a relief of micro structured bumps; stacking the first and second elastomeric carriers across the spacer such that the at least two adjacent electrically conductive leads face the electrically resistive layer across a gap defined by the spacer to form a pocket structure including a gas flow restrictor, the pocket structure defining a gas confining structure that is filled with a gas that at least partly counteracts a force exerted on the pressure sensor and wherein the first carrier including the at least two adjacent electrically conductive leads and the second carrier including the electrically resistive layer are stretchable so as to, upon receiving the force exerted in a direction across the gap, reduce the gap between the electrically resistive layer and the at least two adjacent electrically conductive leads to shunt the at least two adjacent electrically conductive leads with the resistive composite material over a contact area in dependence on the received force to result in a pressure dependent electrical resistance between the conductive leads, and wherein the pocket structure is provided with a relief structure of micro bumps and an opening to reduce the