Abstract: A simply composed, cost effectively manufacturable, pressure sensor is described, comprising a platform, an electrically conductive measuring membrane connected with the platform to enclose a pressure chamber and contactable with a pressure to be measured, and an electrode spaced from the measuring membrane and electrically insulated from the measuring membrane to form together with the measuring membrane a capacitor with a capacitance variable as a function of a deflection of the measuring membrane dependent on the pressure acting on the measuring membrane, wherein the platform has an inner surface bounding the pressure chamber and lying opposite the measuring membrane, wherein an insulating layer is provided on the inner surface, especially an insulating layer of silicon dioxide, and the electrode is a conductive coating, especially a coating of doped polysilicon, applied on the inner surface on the insulating layer.

Abstract: A pressure difference sensor includes a measuring membrane, which is arranged between two platforms and connected pressure-tightly with the platforms, in each case, via a first insulating layer for forming pressure chambers between the platforms and the measuring membrane. The insulating layer is especially silicon oxide, wherein the pressure difference sensor further includes an electrical transducer for registering a pressure dependent deflection of the measuring membrane. The platforms have support positions, against which the measuring membrane lies at least partially in the case of overload, wherein the support positions have position dependent heights, characterized in that the support positions are formed in the first insulating layer by isotropic etching, and the particular height h of a support position, in each case, is a function of a distance from a base of the support position in the reference plane.

Abstract: A pressure difference sensor includes a measuring membrane, which is arranged between two platforms and connected pressure-tightly with the platforms, in each case, via a first insulating layer for forming pressure chambers between the platforms and the measuring membrane. The insulating layer is especially silicon oxide, wherein the pressure difference sensor further includes an electrical transducer for registering a pressure dependent deflection of the measuring membrane. The platforms have support positions, against which the measuring membrane lies at least partially in the case of overload, wherein the support positions have position dependent heights, characterized in that the support positions are formed in the first insulating layer by isotropic etching, and the particular height h of a support position, in each case, is a function of a distance from a base of the support position in the reference plane.

Abstract: In the case of a method for producing a fluid device with a fluid structure having an active height, a basic wafer is provided, which comprises a supporting substrate, an insulating layer on the supporting substrate and a patterned layer on the supporting substrate, the thickness of the patterned layer determining the active height of the fluid structure. Following this, the fluid structure is produced in the patterned layer of the basic wafer, said fluid structure extending through the semiconductor layer. A transparent wafer is then applied so that the fluid structure is covered. Subsequently, the supporting substrate and the insulating layer are removed from the back so that the fluid structure is exposed at a second surface of the patterned layer. Finally, a second transparent wafer is attached to the exposed second surface of the semiconductor layer so that the fluid structure is covered. The essential parameter of the fluid device, viz.

Abstract: In the case of a method for producing a fluid device with a fluid structure having an active height, a basic wafer is provided, which comprises a supporting substrate, an insulating layer on the supporting substrate and a patterned layer on the supporting substrate, the thickness of the patterned layer determining the active height of the fluid structure. Following this, the fluid structure is produced in the patterned layer of the basic wafer, said fluid structure extending through the semiconductor layer. A transparent wafer is then applied so that the fluid structure is covered. Subsequently, the supporting substrate and the insulating layer are removed from the back so that the fluid structure is exposed at a second surface of the patterned layer. Finally, a second transparent wafer is attached to the exposed second surface of the semiconductor layer so that the fluid structure is covered. The essential parameter of the fluid device, viz.