Reluctance motor and associated rotor

What is claimed is: 1 - 15 . (canceled) 16 . A rotor for a reluctance motor, comprising: a laminated core including multiple layers electrically insulated from one another and extending radially away from an axis of rotation of the rotor; at least one magnetically-conductive rotor sheet having multiple flux guidance sections in each layer separated from one another by a non-magnetic area; and at least one insert disk disposed in a non-magnetic area between at least two of the layers, said insert disk being linked to at least two flux guidance sections of at least one of the layers between which it is disposed, so as to connect these flux guidance sections to each other across the non-magnetic area between them, said insert disc being configured in one of two ways, a first way in which the insert disc is woven of fibers having a weave that is aligned at an angle ranging between 40° an 50° to a given q-axis of the laminated core, a second way in which the insert disc is thicker in the non-magnetic area between two flux guidance sections that it connects than a thickness of the flux guidance sections, so as to make a form fit with the flux guidance sections in a radial direction. 17 . The rotor of claim 16 , wherein the insert disc is made of a non-magnetic material. 18 . The rotor of claim 16 , wherein the insert disc has a thickness of less than 0.2 mm. 19 . The rotor of claim 16 , wherein the insert disc comprises a film made of a polymer. 20 . The rotor of claim 16 , wherein the insert disc comprises a resin-bonded knitted or woven fabric. 21 . The rotor of claim 16 , wherein the insert disc is connected to the flux guidance sections by gluing. 22 . The rotor of claim 16 , wherein the insert disc comprises woven fibers, having a weave that is aligned in relation to a given transverse axis of the laminated core at an angle which lies at 45°. 23 . The rotor of claim 16 , wherein at least one of the layers has a number of rotor sheets separated from one another, each sheet forming one of the flux guidance sections of the layer. 24 . The rotor of claim 16 , wherein an insert disc of the said type is disposed in each case between a number of the layers, especially between all layers. 25 . A reluctance motor, comprising a rotor including a rotor having a laminated core including multiple layers electrically insulated from one another and extending radially away from an axis of rotation of the rotor, at least one magnetically-conductive rotor sheet having multiple flux guidance sections in each layer separated from one another by a non-magnetic area, and at least one insert disk disposed in a non-magnetic area between at least two of the layers, said insert disk being linked to at least two flux guidance sections of at least one of the layers between which it is disposed, so as to connect these flux guidance sections to each other across the non-magnetic area between them, said insert disc being configured in one of two ways, a first way in which the insert disc is woven of fibers having a weave that is aligned at an angle ranging between 40° an 50° to a given q-axis of the laminated core, a second way in which the insert disc is thicker in the non-magnetic area between two flux guidance sections that it connects than a thickness of the flux guidance sections, so as to make a form fit with the flux guidance sections in a radial direction. 26 . A motor vehicle, comprising a reluctance motor as drive motor for driving the motor vehicle, said reluctance motor comprising a rotor having a laminated core including multiple layers electrically insulated from one another and extending radially away from an axis of rotation of the rotor, at least one magnetically-conductive rotor sheet having multiple flux guidance sections in each layer separated from one another by a non-magnetic area, and at least one insert disk disposed in a non-magnetic area between at least two of the layers, said insert disk being linked to at least two flux guidance sections of at least one of the layers between which it is disposed, so as to connect these flux guidance sections to each other across the non-magnetic area between them, said insert disc being configured in one of two ways, a first way in which the insert disc is woven of fibers having a weave that is aligned at an angle ranging between 40° an 50° to a given q-axis of the laminated core, a second way in which the insert disc is thicker in the non-magnetic area between two flux guidance sections that it connects than a thickness of the flux guidance sections, so as to make a form fit with the flux guidance sections in a radial direction. 27 . A method for manufacturing a rotor, said method comprising: forming each magnetic layer of the laminated core using a conductive metal sheet that has flux guidance sections in which cutouts are provided as non-magnetic areas between the flux guidance sections; and fitting the metal sheets into the laminated core so that an insert disc is disposed between two of the metal sheets and is connected to at least one adjoining sheet; and impregnating the insert disc with a synthetic resin after fitting all the metal sheets and insert discs, so that the resin penetrates between the flux guidance sections into the non-magnetic areas and the insert disc thus becomes thicker. 28 . The method of claim 27 , wherein the insert disc is made of a knitted fabric or a woven fabric. 29 . The method of claim 27 , further comprising removing an outer ring of each of the magnetically-conductive sheets after the fitting of the metal sheets, so that each of the metal sheets is separated into a number of rotor sheets that are separate from one another.